BE1026079B9 - ABSORBING STRUCTURE - Google Patents

Abstract

The present invention is related to an absorbent structure, preferably for use in absorbent products, such as used in the food, consumer, household, construction and construction, beauty and medical industry, and as used in the personal hygiene industry. The absorbent structures contain a support layer, an auxiliary layer and absorbent material therebetween with the primary compounds and secondary compounds joining the support layer and auxiliary layer, the secondary compounds dissolving due to exposure of the structure to liquid and the primary compounds remaining essentially intact . Furthermore, the absorbent structure of an embodiment of the invention swells non-homogeneously to form a fluid control surface structure due to exposure of the structure to liquid. The present invention meets the need for improved flexible, thin, lightweight absorbent structures which overcome absorption problems of the prior art with regard to absorption, distribution and storage of fluids with optimum fit.

Description

ABSORBING STRUCTURE

The invention relates to an absorbent structure with a high concentration of absorbent polymeric material within an integrated fluid management system.

Absorbent structures with a high concentration of absorbent polymeric material are known. WO95 / 26209, hereby incorporated by reference, describes an absorbent structure useful in the collection of urine and menstruation, with a region of absorbent polymeric material in a concentration of about 60% to 100% by weight. High concentrations of absorbent polymer material in homogeneous and continuous amounts of about 50-100 g in the absence of any substantially fibrous support material lead to very poor fluid management. Poor fluid management or management means that the regions of absorbent polymeric material have insufficient integrity in a dry, partly moist and / or wet state. This results in that the physical continuity (and thus the ability to receive and transport liquids through interstitial cavities and capillaries) of the hydrogel formed after swelling in the presence of liquids is substantially disrupted and altered. Thus, during normal conditions of use where stress and torsional forces are placed on an absorbent structure with poor fluid management, the hydrogel layers will be unintentionally divided, provided with openings, have surfaces that are considerably diluted and / or split into a large number of poorly performing components, whereby cohesion, permeability and conductivity of the absorbent structure are minimized or completely eliminated resulting in performance failure. Adding bulk to the absorbent structure to manage moisture results in an increasing thickness, increases weight, reduces flexibility, and adversely and undesirably affects the cost and ecological footprint of the absorbent article.

WO95 / 21596 discloses an absorbent product formed from two fiber layers between which absorbent particles are arranged. The two fiber layers are laminated according to a combination of permanent and semi-permanent connections.

GB 2283680 describes an absorbent product with connecting means that secure the carrier layers along connecting zones to provide a non-water-sensitive connection between them, which zones are spaced apart from the islands of absorbent material.

2011/0599

The goal is accordingly to obtain thin, flexible, lightweight absorbent structures with a high concentration of absorbent polymer material with good moisture management, taking into account production, marketing, design, fit, comfort, distribution, packaging, removal, material, energy and transport costs. , etc.

The invention is characterized by claim 1.

According to a possible embodiment, the absorbent polymeric material is immobilized in smaller enclosures and larger compartments, characterized in that these enclosures and compartments adequately manage the absorbent polymeric material in a dry, partial and fully fluidized state, subject to the substantially remaining primary connection grids. and substantially temporary secondary connection patterns. These compounds allow sufficient immobilisation, but not excessive limitation, of the absorbent material upon swelling and expansion during fluid uptake, thereby avoiding unauthorized use, loss or adverse impact on their performance.

Preferably, the absence of excess or complete elimination of synthetic immobilization aids (e.g., adhesives and binders, such as thermoplastic adhesives and networks), sometimes used for covering, fixing or bonding absorbent polymers, makes the absorbent structure technically, ecologically and economically very beneficial.

The present invention provides an absorbent structure with many functional and structural integrity for use in an absorbent article such as but not limited to feminine hygiene products, diapers and diaper pants, incontinence products for adults, various absorbent containers, liners, cloths, insertion requirement and so on.

Absorbent structures according to a preferred embodiment of the invention contain an absorbent material, such as, for example, absorbent polymeric material, preferably absorbent particulate polymeric material, such as well-permeable SAP. Prior art absorbent structures are predominantly homogeneous until the available fluid uptake capacity of the absorbent material is reached and / or the available free spaces within the various absorbent structure boundaries are occupied by the swollen and void-expanded absorbent materials. Since there is no macroscopic fluid management structure in those absorbent structures, there is a very high risk of side ics and therefore there is a need to provide additional and compliant surface and / or side barrier structures over the absorbent article.

2011/0599

It has been found that when absorbent polymer material absorbs and swells liquid, it actually performs faster, more effectively and more efficiently when it is located in certain patterns or arrangements. These predefined locations together with a meticulous dosage of absorbent polymeric material helps to achieve optimum absorption, fit and / or comfort.

Hence, since it is desirable that the absorbent polymeric material remain in the intended location and thus prevent unwanted migration and uncontrolled movement thereof within the absorbent structure, the absorbent material is desirably immobilized and / or restrained via the absorbent structure in such a way. structure that the absorbent particle polymeric materials performs in both partially fluid and fully fluid state.

The absorbent structure according to the invention with a carrier layer, an auxiliary layer and an absorbent material between said carrier layer and auxiliary layer provides a sandwich structure in which predefined grids and primary and secondary compound grids join these enveloping layers characterized in that the secondary compounds release , dissolving, weakening and / or being broken as a result of exposing this structure to liquid, vapor and / or moisture while the primary compounds remain substantially intact under such normal conditions of use.

Connections, Connections and Connections as used herein refers to comprising configurations in which one element is directly attached to another element by directly applying the element to the other element, as well as configurations in which the element is indirectly attached to the other element by applying of the element on an intermediate member or members in turn attached to the other element, are synonymous with terms such as confirm, affix, secure, bind, link, etc.

The absorbent structure is distinguished by its ability to securely enclose, immobilize, and / or control absorbent material in the dry state while additional, predetermined, and controlled expansion from a plurality of smaller enclosures to fewer, but larger in size, unchained compartments during wetting. of the absorbent structure

2011/0599 allowed whereby extra (not yet available) space, volume and surface area are created in the light of an optimal expansion, swelling and / or loading of the absorbent material. While the primary compounds primarily help to protect the structural integrity of the absorbent structure, since they are substantially wet-resistant, the secondary compounds will allow the emergence of unprecedented functionalities, while still securely encapsulating the absorbent material during the gradual expansion and swelling.

The absorbent structure joining gratings and patterns are preferably in line with the forces to be exerted during fluid uptake by the available and useful absorbent material from a substantially dry to a partially charged to a fully fluid loaded state. The primary compounds essentially retain more integrity during and after absorption than the secondary compounds under the same or similar conditions. The difference in bonding strength between the primary connections and the secondary connections makes it possible to separate the carrier layer and auxiliary layer between the different primary connection regions, or at the level of the secondary connection zones, thus leaving extra space and volume in view of more and free expansion of the absorbent material in a partially or fully liquid state as opposed to in a dry state.

The disclosure of additional volumes and space only during use, leads to various production, storage and transport benefits, since the absorbent materials can now be positioned and clustered more accurately and effectively, given the removal of the initially restraining means during use of deferred liquid management systems that lead to excellent performance and considerable savings in raw materials. Better and controlled moisture distribution and dispersion therefore leads to better moisture communication from less absorbent (eg saturated) to more absorbent areas (eg unsaturated).

For reasons of further improved absorbency, fluid distribution / transport and retention and a lower number of leaks and rewet values, it is preferable that these absorbent structures have pronounced macroscopic surface structures such as heights and elevations and / or depressions and valleys that act as canals, canals and / or dikes to guide the liquid in a desired manner. The absorbent structure consists of a support layer, an auxiliary layer and an absorbent material sandwiched between them, the primary and / or secondary connections bonding said support layer and auxiliary layer, characterized in that the absorbent structure swells non-homogeneously in order to achieve fluid management

2011/0599 surface structure due to exposure of the absorbent material to liquid.

For the sake of optimum flexibility, fit, comfort, discretion, transport and storage efficiency, it is desirable that such three-dimensional macroscopic surface structures only appear and function when needed, i.e. when the product is partially and / or fully wetted with liquid, and are at so preferably not yet present prior to use of the absorbent structure. The invention thus allows indirect functions, in which the "hidden" functions in the dry state are essentially "released" by wetting, whereby essentially three-dimensional structures are "revealed" with a high (er) elevated and / or low (er) lowered functional and structural parts of the absorbent structure. The three-dimensional swelling of the absorbent structure can be caused by differential swelling of the absorbent polymeric material or by the differential pattern of loosening compounds, or by a combination. In a preferred embodiment, the absorbent structure consists of absorbent materials different in volume absorption capacity, with preferably at least 25%, more preferably at least 50%, most preferably at least 100%. By way of example, an originally flat barrier coupled between two areas of high absorption would be released and upright when these areas absorb and swell.

The inventor has found that the ability to create macroscopic surface structures with internal, integrated and superficial fluid and moisture management systems allows unseen fluid management through fluid guidance to desired locations with additional uptake, distribution, transport and storage capabilities resulting in a significant increase in efficiency and effectiveness of raw materials, while limiting gel blocking and rewet, minimizing leakages and structural failure.

Ideally, the fluid uptake by the absorbent structure and the resulting swelling and volume increase is in line with the respective spaces and volumes created by the increasing detachment and release processes of the connection patterns. While the dry immobilisation of the lower volume absorbent material is ensured in the smaller (er) enclosures formed by the combination of the primary and secondary connections, the wet immobilization of the humidified higher volume absorbent material is also continuously guaranteed by the gradual expansion of large (er) compartments defined by substantially intact primary connections after partial and / or complete release of the secondary connection patterns under the influence of liquid, vapor and / or moisture. Since absorbent material increases considerably in volume, it is therefore important to make it absorbent

2011/0599 material to be enclosed continuously. Well-designed absorbent structures allow gradual expansion of the absorbent material without restricting too little or too much and without releasing the secondary connections too late or too early during the gradual wetting and expansion processes. The bonding strength should be sufficient as a function of the required parameters of the absorbent structure and will depend on the article, its size, shape and required service life and performance.

It is noted that when said primary compounds remain substantially intact under the influence of liquid, reference is preferably made to characteristics under relatively normal wear / use conditions, normal use time, average liquid amounts and intervals at room or body temperatures without taking into account exaggerated , intense and / or extreme conditions, such as an abnormally large number of liters of liquid during several days of intense interaction. In that case, although not preferred, initially, permanent primary connections might eventually unload, disconnect, or disconnect. It is clear from the above that such primary compounds which ultimately change to secondary compounds after exposure to prolonged and / or more intense conditions of use than normal also form part of this invention.

In a preferred embodiment, the absorbent material is preferably in direct contact with the bottom of the auxiliary layer and the top of the carrier layer, although additional fabrics, non-woven, wovens, tissue and / or paper layers may be provided to accommodate further fluid and moisture management and integrity.

The absorbent materials are preferably clustered and encapsulated by the enclosures and compartments as formed by the primary and secondary compounds. Preferably, absorbent particle polymeric material is present in an average basis weight of at least about 50 g / m2, preferably at least about 100-200 g / m2, more preferably at least about 300 g / m2, even more preferably at least about 500 g / m2, most preferably at least about 700 g / m2, where preferably the absorbent polymer material constitutes at least 60% by weight supplemented with from zero to an amount of less than 40% by weight absorbent fiber material. Well-drained SAP is preferred.

The absorbent structure is further elucidated on the basis of exemplary embodiments and with reference to the drawings, wherein the figures show the following:

2011/0599

Figure 1 A-D gives a schematic cross-sectional illustration of absorbent structures according to embodiments of the invention.

Figure 2 shows a schematic top view illustration of an absorbent structure according to an embodiment of the invention.

Figure 3 shows a schematic top view illustration of an absorbent structure in partially wetted state according to an embodiment of the invention, with substantially permanent primary connections and the gradual detachment of still connected and already released temporary secondary connections.

Figure 4 shows schematic top view illustrations of absorbent structures according to embodiments of the invention with indication of different cluster locations, shapes and sizes.

Figure 5 shows schematic top view illustrations of an absorbent structure according to embodiments of the invention in dry intact (A), partially wetted and discharged (B) and wet released (C) state.

Figure 6 shows a schematic top view illustration of an absorbent structure according to an embodiment of the present invention, with built-in phased expansion via primary connection frames 113 and secondary connection patterns 117.

Figure 7 shows a schematic cross-sectional illustration of an absorbent structure with phased expansion in the dry state according to an embodiment of the invention.

Figure 8 shows a schematic cross-sectional illustration of a wetted absorbent structure with phased expansion according to an embodiment of the invention.

With reference to Figures 1 AD, 2 and 3, the absorbent structure 14 comprises at least one support layer 101 and at least one auxiliary layer 102, and absorbent material 110. The support layer 101 and auxiliary layer 102 are connected via primary connections 111, optionally via primary connection media for example, a wet-resistant adhesive or binder, and via secondary compounds 115, optionally via secondary compound media such as, for example, a water-soluble adhesive or a wet-resistant hot melt.

2011/0599

Typical examples of methods used to bond material and layers together are, for example, but are not limited to, the use of adhesives such as, for example, a pressure-sensitive adhesive, hardening, chemical links such as, for example, hydrogen and covalent bonds or via the use of ultrasonic and / or other chemical, thermal, mechanical or thermo-mechanical fixing techniques such as, for example, heat sealing, needling, air, entanglement, resistance, water jet pressure, and the like.

In a preferred embodiment, the primary compounds 111 and the secondary compounds 115 are ultrasonic thermo-seals. Typically, thermo-sealing surfaces of the primary connections 111 are relatively larger in surface, tenacity, and / or integrity (then the thermo-sealing surfaces of the secondary connections 115), resulting in an absolute or relatively high (er) separation force. In general, the connections come in various sizes and shapes, such as round, elliptical, rectangular, or square shapes, but are preferably provided with rounded corners to prevent the carrier layer 101 and auxiliary layer 102 from tearing during use. Preferably, the primary compounds 111 are arranged in a grid consisting of rounded elements of which approximately 50% are oriented along an X-axis, and the remainder along an Y-axis. Combinations of elliptical shapes, such as uni-dimensional and bi-dimensional shapes, make excellent primary connections 111.

It is also preferable to design the connections so that they have an average area of at least about 0.5 mm ² , preferably at least about 1.0 mm ² , 2 mm ² or 3 mm ² , even more preferably at least about 16 mm ² . The density of the compounds can also vary, depending on the size of the surface of the individual compounds and the desired separation forces. For compounds with an area smaller than 1 cm ^2, for example, it is advisable to have a density of at least about

Use 100 connections per m ² . In another embodiment of this invention, the primary connections 111 are arranged in a primary connection grid 113 consisting of continuous lines to allow additional fluid distribution and transport, a high separation force and high resistance to the spread of any cracks or cracks in the enclosures 130. leave. The primary connection gratings 113 are carefully designed so that in the wet state, the swollen material remains stable around the places where it was located and / or immobilized in the dry state. If this does not happen, this would lead to splitting and / or

2011/0599 displacement of the wet absorbent material, resulting in faulty moisture management and loss of performance, reduced fit and comfort, even complete failure.

In addition to the primary connections 111 and secondary connections 115, there are also separate regions 119 where there is essentially no adhesion, bond and / or connection between the carrier layer 101 and auxiliary layer 102, thereby creating enclosures 130 in which the absorbent material 110 can be located to form well-designed clusters. The primary connections 111 correspond to a primary connection grid 113, while the secondary connections 115 correspond to a secondary connection pattern 117. Given that the secondary connection pattern 117 will release under the influence of water and the swelling force of the absorbent materials, the secondary connection 115 must have a relatively have low (er) separation force in use. Preferably, the separation force required to break these secondary compounds in use is less than about 5.0 N / cm, more preferably less than about 2.5, 2.0 or 1.0 N / cm, even more preferably less than about 0.75, 0.5 or 0.25 N / cm and most preferably lower than about 0.20 or 0.10 N / cm.

In an alternative embodiment of this invention, a hydro-soluble or water-sensitive adhesive is used as a secondary compound medium. In a more preferred embodiment, both layers are connected to each other via thermo-sealing, most preferably with ultrasonic compounds, without synthetic adhesives. The thermo-sealing surfaces of the secondary connections 115 have relatively small (er) area, tenacity or integrity (than the primary connections 111), resulting in an absolute or relatively low (er) separation force. The thermo-sealing surfaces can exist in different sizes and shapes, but it is preferable to provide at least one sharp edge on the carrier layer 101 and auxiliary layer 102 in order to facilitate tearing apart. Combinations of circular shapes, such as round and dot shapes, are also preferred as secondary connections 115. Elimination of connection media leads to lower raw material and production costs and more environmentally friendly and durable absorbent structures.

As carrier layer 101 and / or auxiliary layer 102, with a typical basis weight in the range of 3-400 grams, one can choose from a variety of materials, such as but not limited to rigid, stretchable or elastic non-woven fabrics or woven fabrics, wetlaid material such as cellulose tissue, paper, film, tissue, perforated films, foam material, thermoplastic material, layers of adhesives

2011/0599 or any materials that are suitable within the absorbent structure 14. The sandwich layers can be made of the same or different materials with different compositions, weights and / or structures. In a preferred embodiment, at least one of the layers of liquid is permeable over at least a portion of its surface, so that liquids can be picked up in the Z direction. In another embodiment, both the carrier layer 101 and the auxiliary layer 102 are liquid permeable. In yet another preferred embodiment, one of the layers is a liquid-permeable non-woven material and the other layer is a substantially liquid-impermeable and possibly breathable polyethylene (PE) film, the non-woven layer being positioned at the location where the liquid flow as the wearer-facing side of the absorbent structure 14 is to be expected in the case of an absorbent article, such as a diaper, while the PE film is positioned away from the location where the liquid flow is to be expected, such as the clothing-oriented side of the absorbent structure in the case of an absorbent article, such as a diaper. In this case, for example, a 22 gsm polypropylene non-woven material from Albis and a 20 μm breathable polyethylene film from Nuova Pansa can be selected.

The enclosures 130 may have a regular shape, an irregular shape, or a combination thereof. Preferred shapes of the enclosures 130 are circular, elliptical or square with a diameter, radius or side greater than about 0.1 mm, 0.2 mm, 0.3 mm, 0.4 mm, 0.5 mm, more preferably greater than about 0.75 mm and less than about 60 mm, more preferably greater than about 1.0 mm and less than about 40 mm and most preferably greater than about 2.00 mm and less than about 10 mm. The absorbent material 110 does not necessarily fill the enclosures 130 entirely since it may be advantageous to leave some void next to the absorbent material 110 or to keep some enclosures 130 completely or partially empty.

The primary connections 111 must essentially withstand the friction and stress during normal use of the absorbent structure 14 and the forces due to the expanding and swelling absorbent material 110 due to the fluid uptake. Preferably, the separation force required to separate the primary connections between the support layer 101 and auxiliary layer 102 is higher than about 0.05 N / cm or about 0.75 N / cm, more preferably higher than about 0.1 N / cm, 0.2 N / cm or 0.3 N / cm, even more preferably higher than about 1.0 N / cm, 1.5 N / cm, 2.5 N / cm and most preferably higher than about 3-5 N / cm. The joint schedules and patterns can consist of different subregions that correspond to different separation forces.

2011/0599

As can be seen in Figures 4 A-B and 5 A-C, the absorbent material pattern formed between the joints can be random or regular, substantially continuous, continuous or insulated, fully covering or partially covering and / or any other suitable combination. Preferably, the absorbent material regions consist of different clusters of absorbent material 110 surrounded by areas where substantially no absorbent material is present, which can act as additional distribution and transport channels through which the flow of fluid can move away from point of administration to further removed available clusters of absorbent material 110. The weight distribution of absorbent material 110 over the absorbent structure 14 may be regular over the main surface or may be profiled, in other words, the basis weight of the absorbent material 110 may depend on the position within the absorbent structure 14. for example, which is highly desirable for use in diaper and nappy pants where one would absolutely and / or relatively more absorbent material 110 want to concentrate near the point of fluid administration. Suitable materials such as, for example, well-drained SAP are offered by Evonik, BASF and Nippon Shokubai. Although preferably the absorbent polymeric material can form up to 100% of the absorbent material 110, it can also be used in combination with other materials such as, for example, cellulose fibers or fluff pulp, but preferably, the absorbent fiber material only forms from zero to less than 40 % weight percentage.

Breaking the secondary connections 115 allows the carrier layer 101 and / or auxiliary layer 102 to deform, stretch, and / or change shape. As a result, the minimum volume enclosures are capable of extending to intermediate volume compartments and ultimately to maximum volume compartments, to accommodate the additional volume of the additional highly expanding absorbent material 110. Thus, an absorbent structure 14 with extensible enclosures is made via additionally activatable and available swelling volumes, so that the absorbent material 110 can be used more effectively and efficiently and the risk of cracking of one or more layers in between is reduced. The additional volume created by the expansion of enclosures can be, for example, about 1% to 5% of the original volume. Preferably, however, it is higher than about 5% to 25%, more preferably higher than about 25% to 50%, most preferably more than about 50% or 100% of the original volume. In an alternative embodiment, the absorbent structure 14 consists of multiple layers of sandwich-like structures, to which the first sandwich structure of support layer 101 - absorbent material 110 - auxiliary layer 102, additional layers of absorbent material and / or complementary layers 100 are added. Such structures can ensure even better liquid absorption performance while maintaining good product integrity, both in a dry and in a wet state.

2011/0599

Figures 6, 7 and 8 show embodiments according to the invention, in which secondary connections 115 consist of relatively weaker secondary connections 115 'and a relatively stronger secondary connections 115, where the weaker secondary connections 115' disengage faster than the stronger secondary connections 115. The different functionalities in the primary compounds 111 and the secondary compounds 115 in combination with the adhesive force differentiation between the weaker secondary compounds 115 'and the stronger secondary compounds 115 allows the design of an absorbent structure 14 with a predetermined, controlled and / or phased volume -expansion of the absorbent structure possible for ultimate fluid management.

In a more preferred embodiment, the absorbent structure 14 consists of weaker secondary connections 115 'at the edge of the absorbent structure 14 whereby the initial and easier expansion of the absorbent material 110 adjacent the longitudinal and / or end edges of the absorbent structure 14 is perpetuated , thereby forming (first) containment or anti-leakage barriers within the absorbent structure 14. Such special internal built-in barrier structures have a large number of pre-use, use and post-use advantages for the construction of disposable absorbent hygiene products, such as absorbent undergarments, diapers or diaper pants. As shown in Figs. 6, 7 and 8, the weaker secondary connections 115 "release to form the primary barriers or ramparts 150, while the stronger secondary connections 115 form the newly created secondary barriers or ramparts 151. The substantially permanent moisture-resistant primary gratings form channels 152 between the primary dikes 150 and / or secondary dikes 151. Because of the time difference between the formation of the primary dikes 150 and the secondary dikes 151, the primary dikes 150 will contain the liquid in the product, where it can be further distributed through the channels 152 and will, for example, be stored in and enclosed by the secondary dikes 151. Of course, combinations and variants are possible.

For example, in a preferred embodiment, one can make dikes in such a way as to get long or spherical depression enclosures substantially surrounded by dikes. Such dikes can be lowered or interrupted in order to create one or more inlets or outlets. The empty space in the enclosure can then mainly be used to store liquids, solids and / or liquids with a high viscosity. In baby diapers or adult incontinence products, such extra dikes can act as a cushion, providing comfort, keeping the skin away from faeces and preventing faeces from

2011/0599 the absorbent article will be squeezed when the wearer exerts pressure, for example when sitting, on the product. Different shapes, sizes, locations and combinations are conceivable.

The invention provides for the use of an absorbent structure according to an embodiment of the invention in an absorbent product selected from, for example, a list of coffee pads, disposable bodywarmers, web-formed detergent articles, filter materials, insulation materials, makeup pads, anti-septic plugs, ladies' hygiene undergarments, diapers, diaper pants, adult incontinence products, preferably the absorbent article is a feminine hygiene article, a baby diaper, a baby pull-up pants or a light-medium-heavy adult incontinence product. The construction of such commercially available products is well known in the art.

An example absorbent article is a disposable baby diaper.

The chassis consists of a casing with a liquid-permeable hydrophilic soft non-woven, partly elastic top layer covered with a rash prevention coating (eg, aloe vera) with good permeability and reduced tendency to rewet; and a liquid impervious breathable laminate underlayer of non-woven and a thin plastic film with the absorbent structure encased between them. The absorbent structure has a support layer and auxiliary layer of non-woven material with an expansion of more than 10% in the cross direction. The absorbent particle polymer material is a well-permeable cross-linked poly-acrylate. The round ultrasonic primary connections have an area of approximately 2 mm 2 and the ultrasonic ellipsoid secondary connections have an area of 1 mm 2 and are approximately 10 mm apart. The chassis further includes elastic side panels, elastic leg barriers and an elastic waist feature to enclose the chassis around the wearer's waist for improved fit and containment. The chassis also includes hook and slab attachment systems on the outer edges of the back region and a loop landing zone region on the outside of the front region. The absorbent structure comprises predominantly permeable SAP with limited amounts of cellulose fibers, fluff pulp and chemically stiffened, modified, cross-linked cellulose fibers. The absorbent structure consists of only a small amount of non-liquid absorbent materials, such as adhesives, binders, plastics, waxes and oils. The diaper also uses a pair of containment walls with elastic members and a recording and distribution layer located between the top layer and the absorbent structure made of highloft. The side panels placed in the back waist region are flexible, expanding and elastic in at least the lateral direction. The absorbent article also contains front ear panels in function of a better fit, containment and aesthetic properties.

Claims (12)

CONCLUSIONS An absorbent structure with a support layer, an auxiliary layer and an absorbent polymeric material between said support layer and auxiliary layer in which substantially permanent primary compounds and / or substantially temporary secondary compounds at least partially connect said support layer and auxiliary layer to a sandwich-like structure with polymer absorbing therebetween material in at least one of the unbound regions characterized in that the primary connections (111) are arranged in a primary connection grid (113) consisting of continuous lines, the substantially permanent moisture-resistant primary grid forming channels (152) between primary dikes ( 150) and / or secondary dikes (151), wherein the absorbent material is arranged according to an absorbent material pattern that is contiguous. An absorbent structure according to claim 1, wherein a substantial temporary secondary bonding pattern contributes to defining a plurality of relatively smaller unbound enclosures that immobilize at least a portion of the dry absorbent polymer material volume present, the substantial temporary secondary bonding pattern gradually releasing due to the exposing absorbent polymeric material to liquid, resulting in decreasing number and increasing volume of unbound regions that immobilize at least a portion of the partially wetted absorbent polymeric material volume, wherein the substantially intact primary connecting grid contributes to define at least one relatively larger compartment that immobilize at least a portion of the wetted absorbent polymeric material volume. An absorbent structure according to claim 1 or 2, characterized in that the absorbent structure swells non-homogeneously into a three-dimensional fluid management surface structure. An absorbent structure according to any of the preceding claims, wherein the compounds are formed at least in part via a thermal, mechanical, physical, chemical and / or preferably ultrasonic process. An absorbent structure according to any of the preceding claims, wherein at least 60% of the absorbent material is absorbent particle polymeric material. An absorbent structure according to any of the preceding claims, wherein at least a portion of the support and / or auxiliary layer is a fabric, non-woven or thermoplastic layer. 2011/0599 An absorbent structure according to claim 2 and one of the preceding claims, wherein at least one enclosure contains absorbent polymeric material, so that in a dry state the absorbent structure is provided with enclosures of substantially equal thickness, and in the wetted state the absorbent structure provides a substantially uneven in thickness liquid management compartments. An absorbent structure according to any of the preceding claims, characterized in that the absorbent capacity of the absorbent structure is at least 100 g / m2, preferably at least 200 g / m2 and more preferably at least a 500 g / m2. An absorbent structure according to any one of the preceding claims, characterized in that in the wetted state the low zone is at least 5%, more preferably 15% or most preferably at least 25% lower than the height of the adjacent raised dike . An absorbent structure according to any of the preceding claims, wherein the secondary connections (115) consist of relatively weaker secondary connections (115 ') and relatively stronger secondary connections (115 "), where the weaker secondary connections (115') release more quickly than the stronger secondary connections (115 "). An absorbent structure according to any of the preceding claims, wherein the secondary compounds use a hydro-soluble or water-sensitive adhesive as the secondary compound medium. An absorbent product comprising an absorbent structure as claimed in any one of the preceding claims, and an envelope with a liquid-permeable non-woven upper layer and a liquid-impermeable breathable laminate lower layer, wherein the absorbent structure is encapsulated between the upper layer and the lower layer.