The present invention relates to an absorbent article.
As a rule, incontinence products for adults are constituted of a liquid-impervious backsheet and a liquid-pervious topsheet and an absorbent core arranged between these two layers. The liquid-pervious layer is intended to be applied closest to the body, whereas the liquid-impervious layer constitutes the outside of the product. The absorbent core should have the capability to rapidly accommodate a relatively large liquid quantity, and the core should further be able to distribute and store the liquid.
The absorbent product has a front portion and a back portion which when in use are positioned in front of and behind, respectively, the user. The front portion and the back portion terminate in a front end region and a rear end region, respectively. In order to make it possible to wear the product securely, some kind of fastening system, having the task of securing the product in its position on a user, is arranged on the product. As a rule, such a fastening system is created by means of the front and rear end regions being provided with interacting fastening members, for example in the form of a hook and loop fastening system, such as a Velcro fastener or, alternatively, a system with adhesive tape tabs. When using a hook and loop fastening system, two zones exhibiting hooks are arranged on two tabs in the rear end region, and two corresponding, separate receiving zones, exhibiting loops for interacting with the hooks when fastening, are arranged in the front end region.
WO 98/38956 discloses an absorbent article which exhibits an absorbent core and a breathable backsheet in the form of a laminate. A continuous receiving zone of a conventional type is arranged on the outside of the backsheet. The receiving zone overlaps a portion of the core in a front region of the front portion of the absorbent article. Furthermore, it is disclosed that the backsheet as such, being in the form of a laminate composed of two different layers, can constitute a receiving zone of a hook and loop fastening system.
The previously known products for incontinent adults, however, have a number of disadvantages. Even though there are different sizes of incontinence products, each respective size is usually optimal only for a smaller group of users, since different individuals have different body sizes. It would be far too costly to adapt the incontinence product to the bodily constitution of an individual. In addition to the fact that a less than optimal fit can make the product uncomfortable to wear, also the function of the product can be impaired if the fit is insufficient. For instance, it is an advantage if a portion of the inner, liquid-pervious topsheet, corresponding to the region around the upper edge of the absorbent core of the front portion can abut and seal tightly against the body. This has the advantage that leakage is prevented. For many users of incontinence guards, this function cannot always be achieved as a result of an insufficient fit.
When the fastening function and thereby the waist size are concerned, the product could be adapted to users of different sizes by means of arranging proportionately large receiving zones for interaction with fastening members, such as hooks or the like, in the front end region of the front portion of the product. On the other hand, however, it is desirable that each respective receiving zone, which usually consists of a material layer being provided with loops, is as small as possible, since such a material layer influences the ductility and flexibility of the product adversely, since the product becomes substantially stiffer in the region where the receiving zone is arranged. Furthermore, such a material layer usually has a much lower breathability than the remainder of the product. Consequently, large receiving zones would result in an inferior comfort and increase the risk of skin irritation because of the lower breathability. Furthermore, it is a fact that larger receiving zones lead to increased material costs which, in their turn, result in a more expensive product.
One object of the invention is to provide an absorbent article exhibiting a receiving means which substantially reduces the above-discussed problem with such previously known articles. Accordingly, the absorbent article according to the invention is provided with a receiving means which, by comparison with the previously known products of the type in question, substantially improves the fit and flexibility of the absorbent article.
A flexible nonwoven laminate is used as a receiving means, wherein the nonwoven laminate and the absorbent core overlap each other so that the overlapping zone created in that way has an extension amounting to at least 45 cm2. The receiving means can be utilised for bringing the absorbent core to abut and seal tightly against the body when in use, directly or via an inner, liquid-pervious layer, so that the function is improved, at the same time as a good ductility and fit are obtained.
By means of using a nonwoven laminate, the article can exhibit a high degree of ductility and flexibility, as well as process engineering advantages and, furthermore, a nonwoven laminate can be produced at a proportionately low cost. Altogether, these characteristics result in the possibility of producing proportionately large receiving zones without sacrificing performance or economy.
The proportionately large overlapping zone is important for obtaining the desired comfort of an incontinence product for adults, said product being very soft and flexible in itself. It has been found that a minimum overlapping zone of the indicated size, as a rule, is required for enabling the desired comfort to be achieved. The proportionately large area of the receiving means which is required in order to obtain the overlapping zone also makes it possible to vary the positioning of the tabs, being provided with e.g. hooks, when fastening the tabs to the receiving means, which means that the waist measurement and, accordingly, the size of the product can be varied to some extent. In addition, a continuous area of the receiving means results in a more efficient production of the absorbent article, since the attachment of a receiving means on the outside of the article usually can be performed with fewer process steps than the attachment of two separate receiving means.
A detailed description of exemplifying embodiments of the invention will follow below, with reference to the attached drawings.
In the drawings:
A receiving means or layer 11 is arranged on the opposite side of the backsheet 2 in relation to the core 1, in order to provide a surface 10 for receiving fastening members 12 arranged on the article. The receiving layer 11 and the fastening members 12 are adapted for being joined together when applying the article onto a user. As illustrated in
The nonwoven laminate 11 and the absorbent core 1 overlap each other so that the overlapping zone 15 created in this way (being shadowed in
The rear end region 8 of the back portion 6 can be provided with two tabs 17. Each respective tab 17 is provided with said fastening members 12, preferably hooks, for enabling it to be attached to the nonwoven laminate 11. The surface 10 of the nonwoven laminate 11 of the outer layer 14, for example carded nonwoven, can provide loops to which loops the hooks can be fastened.
Suitably, the nonwoven laminate 11 is breathable in order to avoid a deterioration of the breathability of the article. The breathability of the nonwoven laminate 11 is preferably larger than or equal to the breathability of the backsheet 2. The breathability of the nonwoven laminate 11, expressed as a MVTR-value (mass vapour transmission rate) can be larger than or equal to 2000 g/m2/24 h, preferably ≧4000 g/m2/24 h, and most preferably ≧6000 g/m2/24 h. The MVTR-value can be determined in accordance with the testing method ASTM E-960.
One example of a nonwoven laminate which is particularly well suited for implementing the invention is a spunbond/carded nonwoven laminate where the spunbond layer constitutes the first, inner layer 13 of the laminate and the carded layer constitutes the second, outer layer 14 of the laminate. For such a nonwoven laminate, the following layers can be used, viz. a white spunbond layer of 100% polypropylene having a basis weight which is 30 g/m2, made of fibres within the interval 2.2 to 2.5 dtex, whereas the carded layer can be a white layer of 100% polypropylene, having a basis weight which is 30 g/m2, made of 2.2 dtex fibres.
A basis weight of the inner and/or outer layer which is lower than 30 g/m2 can be used, however, since the stress normally is not particularly high. Accordingly, a lower basis weight of, for example, 18 g/m2 is normally acceptable. The basis weight is preferably within the interval between 15 g/m2 and 80 g/m2, and more preferably between 20 and 65 g/m2, in order to meet the demands for both strength and softness. Basis weight measurements should be performed by means of using dry materials at a temperature of 21° C. and a humidity of 55%.
The above-mentioned carded layer (white, 100% polypropylene, 2.2 dtex, between 18 and 30 g/m2) can also be used as the surface layer facing outwards towards the garment, onto which surface layer a material section being provided with hook-like members (of a hook and loop fastening system), of a fastening tab which is intended to be utilised when the product has been used, can be attached in a detachable way.
The layers of the nonwoven laminate can be bonded into a laminate by means of using ultrasonics, but also other binding methods, such as gluing, heat welding etc., or combinations of said methods, can be utilised. The same binding methods can be utilised for attaching the laminate to the backsheet. For cost reasons, however, ultrasonic bonding is usually preferred. The total bonded area of the layers can be 3-%, and preferably of the magnitude 5-10%, of the total area of the laminate.
It should be noted, however, that a number of different nonwoven materials can be utilised for creating the laminate.
The nonwoven laminate suitably has a stiffness (Peak bending stiffness) which is equal to or lower that 40 gf (gram force), and preferably the stiffness is lower than gf. The stiffness is measured in accordance with the modified testing method disclosed in U.S. Pat. No. 5,009,653. The testing method is a modification of ASTM D 4032.82 “CIRCULAR BEND PROCEDURE”.
Advantageously, the nonwoven laminate can be made liquid-pervious. As a rule, a liquid-pervious laminate requires a lower level of quality control, since larger tolerances of the material can be accepted, something which in its turn can rationalize the production and offer savings.
The liquid-pervious topsheet 3 can be made of a nonwoven material, such as spunbond, meltblown, carded, hydroentangled, wetlaid nonwoven, etc. Suitable nonwoven materials can be composed of natural fibres, such as cellulose or cotton fibres, manmade fibres, such as polyester, polyethylene, polypropylene, viscose, etc. or a mixture of natural fibres and manmade fibres. Furthermore, the topsheet material can be composed of tow-fibres, which can be bonded to each other in a bonding pattern, as disclosed in e.g. EP-A-1 035 818. Additional examples of topsheet materials are porous foams, apertured plastic films, etc. The materials being arranged as topsheet material should be soft and not cause any skin irritation and allow easy penetration of body fluid, such as urine and menstrual fluid. Furthermore, the topsheet can be different in different portions of the absorbent article.
The liquid-impervious backsheet 2, covering the core region on the side of the article facing outwards towards the clothes when in use, is made of a liquid-impervious material, such as a thin plastic film, e.g. a polyethylene or polypropylene film, a nonwoven material coated with a liquid-impervious material, a hydrophobic nonwoven material counteracting or preventing liquid from penetrating the material, or laminates of plastic films and nonwoven materials. The backsheet can be breathable at the core region in order to allow water vapour to be emitted from the absorbent core, while liquid still is prevented from passing through the layer.
Examples of breathable backsheet materials are porous films, nonwoven laminates of spunbond and meltblown layers, laminates of porous polymer films and nonwoven materials. Preferably, the backsheet is inelastic.
Films made of polyolefins filled with solid particles (e.g. a mineral such as calcium carbonate) can be mentioned as examples of backsheets of the article. In certain conditions, these films are known to form porous structures, enabling diffusion of water vapour while a liquid barrier is provided. This is a desirable characteristic of hygiene articles of different types. A considerable part of the comfort of an absorbent article is actually its ability to maintain a balance between heat generation and heat loss. Heat loss through a covering can arise from direct, dry heat loss, or from evaporation of moisture. When the latter phenomenon is concerned, the rate at which moisture is transformed into vapour by the material being used in order to form the garment or the absorbent article is generally related to the breathability of the material. The breathability is the ability to diffuse moisture/water vapour through a film or an absorbent article. In addition to this characteristic, there are many applications requiring that the material which is used in order to achieve the absorbent article is liquid-impervious. Such applications include backsheets of diapers and incontinence guards, panty liners, medical protective articles, sterile dressings, plasters, bandages, guards for intravenous and ostomic treatment, breathable construction membranes such as protective fabrics for house foundations etc.
Films which allow water vapour to pass through and are porous, but which still are intended to be impervious for liquid, are disclosed in U.S. Pat. Nos. 4,626,252 and 5,073,316. As described therein, a porous film is obtained by means of mixing a polyolefin plastic, an inorganic filler and a softener; forming a film of the mixture; and uniaxial and biaxial stretching of the film. Films of this type are also disclosed in U.S. Pat. No. 5,998,505 and the PCT-application with publication number WO98/05501.
It is emphasised that the invention is not restricted to the embodiments of the invention which have been described as examples, but a number of variants and modifications of the invention within the scope of the following claims will become obvious to the skilled person once the inventive idea has been disclosed.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/SE2004/001176 | 8/6/2004 | WO | 00 | 2/1/2007 |