The present invention relates to an absorbent article. The present invention in particular relates to an absorbent article having a soft surface layer with an improved embossing pattern.
Disposable absorbent articles, such as pantiliners, sanitary napkins, adult incontinence devices and diapers, of the kind to which this disclosure relates are worn against the skin and are used to absorb bodily fluids. The absorbent articles include a topsheet and a backsheet layer, and may also conventionally include an absorbent core therebetween.
All uses of products which are applied in direct contact with the skin sometimes experience skin problems. Skin problems can be caused by forces arising from physical/mechanical interaction between the absorbent product and the user's skin. Thus, for example chafing is caused due to extra friction between the absorbent product and the 20 skin of the user. The mechanical friction between the material and the skin of the user is different in the presence of liquid/moisture than when no liquid/moisture is present.
Absorbent articles may have printed or embossed patterns imposed upon their surfaces. For example, sanitary protection articles, such as, napkins, pantiliners, and incontinence 25 devices, typically have a liquid permeable surface layer provided with a pattern of depressed areas embossed into the surface in such configurations as flowers or other feminine designs. Other patterns may take the form of various geometric shapes, such as, circles, diamonds, squares, curves, or other stylized figures, such as, stars, spots, or the like.
While articles are embossed mainly for decorative purposes, embossing may communicate or provide a function to the user of such an article. For example, it is known that embossing functions in impeding or directing fluid flow. Embossing is also done to provide a visual cue to show differences in the material surface. To provide the desired aesthetical effect, embossing patterns may usually be imprinted relatively deep; e.g., the depressed areas may be permanently depressed to a degree, which represents a major portion of the thickness of the product.
It is an object of the present invention to provide an absorbent article having a distinct embossing pattern as well as having improved skin benefits.
One or more of the above objects may be achieved with an absorbent article in accordance with claim 1. Further embodiments are set out in the dependent claims, in the following description and in the drawings.
The absorbent article as disclosed herein has longitudinal side edges extending in a longitudinal direction and transverse front and rear end edges extending in a transverse direction. The absorbent article comprises a fluid permeable surface layer and a backsheet. The fluid permeable surface layer is an embossed surface layer comprising an embossing pattern covering from 3% to 20% of the total surface area of a wearer-facing portion of said surface layer. The surface layer is an air-through-bonded fibrous nonwoven surface layer comprising synthetic fibers and has a basis weight of from 14 to 30 g/m2.
The term “absorbent articles” refers to products that are placed against the skin of the wearer to absorb and contain body exudates, like urine, faeces and menstrual fluid. The disclosure mainly refers to disposable absorbent articles, which means articles that are not intended to be laundered or otherwise restored or reused as an absorbent article.
Examples of disposable absorbent articles include feminine hygiene products such as sanitary napkins and panty liners, incontinence pads and diapers and the like.
The air-through-bonded fibrous nonwoven surface layer having a basis weight of from 14 to 30 g/m2 has been found to enhance the optical appearance of an embossing pattern by increasing the distinctness of the embossing pattern. One reason may be that such an air-through bonded fibrous nonwoven has relatively low number of bonding points between the fibers within the material which enhances the visibility of the embossing pattern when provided on the material.
The synthetic fibers may be bicomponent fibers. The bicomponent fibers may have a sheath of polyethylene or polyprophylene. The core may be of polyester. To use synthetic fibers in the air-through-bonded fibrous nonwoven wherein at least the sheath of the fiber is of polyethylene has also been seen to render the embossing pattern more distinct which may result from breaking of the fiber structure during embossing.
To use synthetic fibers in the air-through-bonded fibrous nonwoven wherein the sheath of the fiber is of polyester (PET) has also been seen to render the surface material more resilient.
Air-through-bonded fibrous nonwoven material comprising sheath-core bicomponent fibers, and particularly wherein the core is a polyester core and the sheath is a polyethylene sheath, has been seen to provide improved and distinct embossing patterns which may result from breaking of the bicomponent fiber structure during embossing and the polyester core is beneficial for enhancing the resiliency of the nonwoven structure.
The fluid permeable surface layer is an embossed surface layer comprising an embossing pattern covering from 3% to 20%, or 5% to 16%, of the total surface area of a wearer-facing portion of said surface layer. This has been found to provide a soft and compliant surface sheet with a good visibility of the embossed elements. If a too large extent of the surface area of the surface layer is provided with embossing pattern, the surface layer becomes too stiff. The fluid permeable surface layer may have an embossing free area in the crotch portion of the article corresponding to the liquid inlet area so as to maintain a relatively low density (=high bulk) in the liquid inlet area which is beneficial for the liquid inlet rate.
By “wearer-facing portion” of the surface layer means the portion of the surface layer facing the wearer during use of the absorbent article. The absorbent article may for example comprise wings or flaps provided with attachment means, such as adhesive. The surface layer may extend over the wings of the absorbent article, however the “wearer-facing portion” does not include wings or flaps as these are not intended to face the wearer during use. To determine the “wearer-facing portion” of the surface layer for an absorbent article comprising wings or flaps, a straight line is drawn between a starting point and an end point of the respective wing along the respective longitudinal side of the absorbent article, i.e. the start and end point being where the contour of the absorbent article curve outwardly to form the respective wings.
The embossing pattern may comprise embossed continuous and/or discontinuous lines having a minimum width of 0.3 mm or 0.6 mm or 0.9 mm. The maximum width may be 5.0 mm, or 3.0 mm. The discontinuous lines may comprise or consist of embossed dots arranged in a discontinuous line, such as a straight or a curved line and/or embossed pattern of different kind. The embossed dots may have a minimum diameter of 0.3 mm, or 0.6 mm or 0.9. The maximum diameter may be 5.0 mm, or 3.0 mm.
The embossing pattern may have a minimum depth of 0.3 mm, 0.4 mm or 0.5 mm. The maximum depth may be 3 mm.
The bi-component fibers in the embossing pattern may be permanently deformed but not consolidated.
The surface layer may have a density of from 20 to 90 kg/m3, 20 to 60 kg/m3, 20 to 40, 15 to 40 kg/m3 or 20 to 30 kg/m3. The air-through-bonded surface layer has a relatively low density, and this means that there is a relatively high amount of void space between the fibres. The density can be calculated by dividing the basis weight of the surface layer by its thickness measured at a pressure of 0.5 kPa
The fibers of said air-through-bonded nonwoven surface layer may have a coarseness of from 1.8 to 10 dtex, or 2 to 7 dtex or 3.5 to 7 dtex.
The surface layer may be free from lotions and/or lubricating agents. As the surface layer in it-self has been found to provide the surface layer with surprisingly low friction values both under dry and wet conditions, lotions and lubricant agents may not be needed to decrease the friction between the nonwoven and the user's skin.
The surface material may be hydrophilic. A hydrophilic material may be obtained by adding a surfactant.
The absorbent article may comprise an intermediate layer, such as an intermediate 35 fibrous layer, located between the surface layer and the backsheet and in direct contact with the surface layer. The intermediate layer may be a nonwoven layer such as airlaid or high-loft nonwoven materials, such as for example air-through-bonded nonwoven or hydroentangled nonwoven material.
The intermediate layer may extend under from 70% to 100% of the wearer-facing portion of the surface layer.
The surface layer and the intermediate layer may be adhesively attached to each other. This may increase the integrity of the surface layer. The fact that the surface layer has a relatively low density with relatively low number of bonding points between the fibers gives a structure with lower integrity. However, when combining the air-through-bonded fibrous nonwoven surface layer with an intermediate layer having a lower elongation than the air-through-bonded fibrous nonwoven, the air-through-bonded fibrous nonwoven surface layer integrity is increased. Both during use of the absorbent product as well as during manufacturing it is advantageous that a structure(s) has a sufficient integrity.
It is also possible to attach the liquid surface material with the intermediate layer by thermo- and or mechanical welding, for example by ultrasonic welding. By this, the lamination and embossing may be done in the same step.
According to one embodiment, only the fluid permeable surface layer of the sanitary is embossed and not the intermediate layer. However, according to another embodiment the embossing is done also through the intermediate layer, so that also the intermediate layer is embossed. Furthermore, it is also possible to emboss through the surface layer, the intermediate layer and also through a further layer such as for example an absorbent core which may be arranged between the intermediate layer and a backsheet. If the liquid surface material is laminated together with the intermediate layer through thermo- and or mechanical welding, the lamination and embossing may be done in the same step. One embossment may penetrate both the fluid permeable surface layer and the intermediate layer, for example by ultrasonic welding.
The backsheet has a garment facing side and an adhesive may be arranged on said garment facing side.
The absorbent article may include an absorbent core arranged between the surface layer and the backsheet and between the intermediate layer and the backsheet if the absorbent article comprises an intermediate layer. The absorbent core may for example include pulp fibers or may comprise a mixture of superabsorbent particles and pulp fibers.
The backsheet may be a breathable or non-breathable plastic film. The backsheet may be a polyolefin plastic film. The backsheet may also be a laminate of a plastic film and a nonwoven material.
The absorbent article may be a sanitary napkin.
The present invention will be further explained hereinafter by means of non-limiting examples and with reference to the appended drawings wherein:
The invention will be described more closely below by reference to an exemplary embodiment. The invention may however be embodied in many different forms and should not be construed as limited to the embodiments set forth in the drawings and the description thereto.
The fluid permeable surface layer 8 comprises an embossed pattern 11. The embossed pattern 11 comprises individual embossed elements 11a in the form of dots forming a pattern covering from 3% to 20% of the wearer-facing portion of the surface layer 8. At a rear end 12 of the absorbent article 1, the surface layer 8 is provided with an embossed wing-shaped continuous line 11b and a continuous embossed line extends along a contour of the absorbent article 1 framing the embossed pattern 11.
The absorbent article 1 in
The backsheet may be a breathable or non-breathable plastic film. The backsheet may be a laminate of a breathable or non-breathable plastic film and a nonwoven material.
The absorbent core may be of any conventional kind. Examples of commonly occurring absorbent materials are cellulosic fluff pulp, tissue layers, highly absorbent polymers (so called superabsorbents), absorbent foam materials, absorbent nonwoven materials or the like. It is common to combine cellulosic fluff pulp with superabsorbents in an absorbent structure. It is also common to have absorbent structures comprising layers of different material with different properties with respect to liquid acquisition capacity, liquid distribution capacity and storage capacity. This is well-known to the person skilled in the art and does therefore not have to be described in detail. The thin absorbent bodies, which are common in today's sanitary articles, often comprise a compressed mixed or layered structure of cellulosic fluff pulp and superabsorbent. The size and absorbent capacity of the absorbent structure may be varied to be suited for different uses such as sanitary articles, pantyliners, adult incontinence pads and diapers, baby diapers, pant diapers, etc.
The intermediate layer may be composed of for example airlaid nonwoven, high loft nonwoven such as for example air-through bonded nonwoven or hydroentangled nonwoven. An air laid nonwoven can be produced with fluff, wood pulp, and here the fluff fibres are dispersed into a fast-moving air stream and condensed onto a moving screen by means of pressure and vacuum. The web can be bonded with resin and/or thermal plastic resin dispersed within the pulp. The web can be thermobonded (by heat), latex bonded (with adhesive) or multibonded (a combination of thermo and latex bonding) or mechanically bonded (high compression and temperature, bonding by hydrogen). The grammage of the airlaid nonwoven can suitably be from 50 to 100 gsm.
High loft is a nonwoven material and may be substantially free from absorbing fibres and superabsorbent material. The high loft nonwoven material may comprise thermoplastic polymer fibres, and may be selected from but not limited to, polyesters, polyamides and polyolefins such as polyethylenes (PE) and polypropylenes (PP), and may be a mixture of any of these. The “high loft” refers to low density bulky fabrics, as compared to flat, paper-like fabrics. High loft webs are characterized by a relatively low density. This means that there is a relatively high amount of void space between the fibres. The intermediate high loft nonwoven layer may typically have a density below 200 kg/m3, in particular ranging from 15 kg/m3 to 150 kg/m3, in particular from 30 to 100 kg/m3. The average density can be calculated by dividing the basis weight of the high loft layer by its thickness measured at a pressure of 0.5 kPa. Normally the thickness of the intermediate layer of high loft material is more than about 0.5 mm, such as more than 1 mm or suitably 1.5-2.0 mm, and the solid content is low, usually less than 15% by volume.
The raw material for the intermediate layer may be polyolefines, for example be polypropylene (PP), polyethylene (PE), or polyester (PET), polyamide (PA), cellulosic fibres or a combination of these. Thus, if a combination of different fibres is used, this can be a mixture of fibres from different polymers, although each fibre can also include different polymers (e.g. PP/PE bi-component fibres or PP/PE copolymers).
Where appropriate, the plastic backsheet film may comprising PE or PP, PET, PLA or amyl (or, for that matter, any other thermoplastic polymer), or a mixture or copolymers of the aforementioned polymers.
In
Embossing Measurement
The depth of the individual embossed elements in the form of dots have been measured by the method ISO25178 and also the depth of a continuous embossed line extending along a contour of the absorbent sanitary napkin framing the embossed pattern comprising the individual embossed elements have been measured by the method ISO25178.
Three different sanitary napkins were tested having different surface layers but otherwise constructed with the same underlying materials and compared in terms of diversity of embossment depth. The test material is an air-through-bonded nonwoven according to the present disclosure comprising bicomponent fibers of core-sheath type with a polyester core and a polyethylene sheath. The first Comparative Example is a spunbond nonwoven with polypropylene fibers and the second Comparative Example is spunbond nonwoven with polypropylene fibers. Table 1 below provides specifications of the materials tested.
In Table 2 shows the result of the mean individual depth of the individual embossed elements (μm) and the standard deviation of the depth (μm).
The result shows that the standard deviation of the depth value of the embossment element for the air-through-bonded nonwoven. The standard depth deviation for the Test sample was lower than the standard depth deviation for the comparative example 1 (Cex 1) and the comparative example 2 (Cex 2).
The mean individual depth of a continuous embossed line, a “valley”, for the air-through-bonded nonwoven according to the Test sample, as seen in table 3, has a lower ratio between Standard deviation and Mean individual depth than the Comparative example 1 (Cex 1) and the Comparative example 2 (Cex 2).
So, both the standard deviation of the mean depth of the individual embossed elements in the form of dots, and the ratio between Standard deviation and Mean individual depth of a continuous embossed line extending along a contour of the absorbent sanitary napkin framing the embossed pattern comprising the individual embossed elements shows that the air-through-bonded nonwoven surface material has more distinct embossed elements that enhances the visibility of the embossing pattern when provided on the material.
Also, the enlarged photos in
Friction Measurement
Friction occurring between a nonwoven material and the skin of the user is different in the presence of liquid/moisture than when no liquid/moisture is present. Even a very small amount of moisture present originating from perspiration, sweat or other body fluids has an impact on the friction forces occurred between the nonwoven material and the skin of the user. It has therefore been discovered that it is really important to carefully choose the nonwoven characteristics, so that the nonwoven is able to minimize the mechanical discomfort during the overall use of the product.
The method used for the friction measurement was the Stick and slip measurement method which is described in detail in WO 2016/114693. The friction measurement has been performed according to the description in WO 2016/114693.
The method measures the static friction, sns value (stick and slip value) in gram force, gmf, between a material and the human skin. The method means that repeatedly runs are made using the same material strip. First the sns value for the dry state (dry material and skin) is measured followed by wet state at different liquid levels (from completely wetted material, to moist and to almost dry) until the sns value is back to the skin-material interaction level measured in the first dry run, which mean that the material is dry again.
The method is thus called a repeated stick and slip method or sns dry-wet-dry. The stick and slip value is defined as the point on the force curve (gmf) where the material starts gliding over the arm. The sns values from all single force curves are then put together in a new graph, sns values as a function of number of runs.
Three different nonwoven materials were tested and compared in terms of dry friction and wet friction. The test material is an air-through-bonded nonwoven according to the present disclosure comprising bicomponent fibers of core-sheath type with a polyester core and a polyethylene sheath. The first Comparative Example is a spunbond nonwoven with polypropylene fibers and the second Comparative Example is spunbond nonwoven with polypropylene fibers. Table 1 above provides specifications of the materials tested.
In table 4 below shows result of the mean friction plateau values measured in gmf. By gmf is meant gram-force and one gram-force is 9.80665 mN and the result shows that the test sample, the air-through-bonded nonwoven surface material has a lower mean friction plateau value (gmf).
Also in
Density Measurement
The density is calculated by dividing the basis weight of the surface layer by its thickness. The thickness is determined by means of a measuring foot with affixed load of 0.5 k Pa. The measuring foot has an area of 50×50 mm2. The thickness is read off at the digital thickness gauge/tester after 10 seconds when the measuring foot has touched the surface of the sample.
Filing Document | Filing Date | Country | Kind |
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PCT/SE2019/050131 | 2/15/2019 | WO | 00 |