KR20000069579A - A dry laid structrue comprising particulate material - Google Patents

Abstract

The present invention relates to a dry laminated fibrous structure 40 for absorbing aqueous fluids and / or for suppressing odors. The fibrous structure 40 comprises a dry laminated fibrous web 22 and particulate material distributed within the web, bonded by a thermoplastic polymer material in finely divided form 48 therein, in particular the fibrous structure 40 ) Is suitable for use as a disposable absorbent product.

Description

Dry laminated fibrous structures and disposable absorbent products {A DRY LAID STRUCTRUE COMPRISING PARTICULATE MATERIAL}

Fibrous structures, in particular fibrous structures for absorbing liquids, can be used in various applications, for example, disposable diapers as fluid absorbing or fluid passing and / or diffusing elements (such as absorbent cores for absorbing and retaining body secretions), It is made of absorbent articles such as incontinence pads and sanitary napkins. Fibrous structures, and in particular fibrous structures used in absorbent articles as fluid absorbing or fluid passing and / or diffusing elements, generally include a number of components to enhance certain performance, for example, in fiber and particulate form. Absorbent structures comprising particulate materials such as phosphorus absorbent gelling materials are known in the art. Other components can be used to provide additional advantages to the structure.

Dry laying, in particular air laying processes, has been widely used to produce webs from dry fibers, which have been used, for example, as structures for absorbing fluids. In particular, dry lamination means that the fibers form carded webs that are oriented [carded] in a given direction, whereas air lamination means forming a web with complete random fiber orientation. Meaning that the properties of the air layer web are somewhat isotropic. Fibrous webs produced by dry lamination are soft, flexible, porous, and are particularly suitable for use as liquid absorbent structures in absorbent articles such as disposable diapers, sanitary napkins, incontinence pads, and wipes.

For example, methods of incorporating other components in particulate form into dry laminated fibrous webs are known in the art, and in particular US Pat. No. 4,765,780, an absorbent gelling in which one layer is uniformly mixed in particulate form therein. A method and apparatus are disclosed for forming an air layer fibrous web comprising a plurality of components, such as the two layer absorbent core, wherein the other layer is substantially free of absorbent gelling material particulates. To provide an absorbent structure composed of dry laminated fibrous webs having other advantages, such as malodor suppression, similar techniques for using other types of components in dry laminated fibrous webs, for example, malodor suppression means in particulate form, may be employed. Can be used.

Dry lamination processes generally include web formation and layering steps, web bonding and stabilization steps, and in dry laying processes, for example in the form of cellulose fibers, synthetic fibers or combinations thereof. Fibers, which may be formed into the web or condensed in the web. Other components that are not in fiber form may be used, for example, in a fibrous web that is a particulate material. The resulting web lacks integrity after molding and must therefore be stabilized. Other techniques for bonding and stabilizing dry formed webs are known in the art and include, for example, mechanical, thermal and chemical bonding methods. The method of joining the web structure by chemical means is one of the most common bonding methods in the nonwovens industry, and has a configuration in which a chemical binder is added to the web and the binder is cured. The most widely used chemical is latex, because the latex is inexpensive, versatile, easy to apply, and very effective as a binder. Although various methods of adding latex binders to fibrous webs are known, spray bonding and print bonding are particularly preferred for fibrous webs used as absorbent articles.

EP-A-592 001 discloses a nonwoven fabric bonded by means such as, for example, a latex binder, which nonwoven fabric is distributed in a discontinuous pattern on at least one of its surfaces. And "odor particles" in the form of a powder comprising "particles" or "globules" of the thermoplastic composition and attached to the thermoplastic "particles" or "spheres" on the surface of the nonwoven fabric. In this case, all malodor control materials are attached to the thermoplastic “particulates” and are only present on the surface of the nonwoven structure.

European patent application EP-A-463 716 discloses a dry laminated absorbent structure, the dry laminated absorbent structure comprising a fibrous web having an absorbent gelling material therein, by latex coating at least one surface of the web. Stabilizes.

Thermal bonding methods are widely used to join dry laminated webs, which include fusible fibers such as bicomponent fibers, monocomponent fibers, or blends with non-fusible fibers, for example natural fibers. The fibers are continuously melted by heat treatment to bond the web structure.

International patent applications WO 94/01069 and WO 95/17868 disclose thinly laminated absorbent structures, which are typically two independently formed outer fibrous layers, a typical air layer cellulose tissue layer, And an intermediate layer comprising particulates of the absorbent gelling material and particulates of the thermoplastic polymer material, wherein the two fibrous layers are joined by a melt of thermoplastic particulates. When the laminate structure is manufactured, the fibrous layer is already formed and joined, thus making up two different and separated layers connected to form the stacked structure, wherein the particulate material is distributed only between the fibrous layers.

When chemical and thermal bonding methods as well as combinations thereof are applied to the dry laminate comprising particulate material in the dry laminate, particularly when the particulate material used in the dry laminate is preferably concentrated between the thicknesses of the webs. The method has drawbacks, thus forming areas of the web where the fibers are composed of low percentages. In such a case, the latex composition can barely penetrate the thickness of the web to reach the microparticles, and if the latex composition is not used in such an amount, it impairs the performance of the whole structure and adversely affects the particulate material if possible. On the other hand, for example, when using melt fibers, which are bicomponent fibers, the resulting heat treatment does not solve the problem, because the fibers are not distributed between the particles in an amount capable of performing an effective bonding action. In addition, due to the different properties of the fibers as compared to the particulate material, it is difficult to obtain a uniform distribution of the fibers between the particulate materials when the particulate material constitutes a high percentage of the mixture. Fibers that can be melted in heat, such as bicomponent fibers, are expensive.

It is therefore an object of the present invention to provide an air layer fibrous structure comprising a dry laminated fibrous structure, preferably a dry laminated fibrous web and particulate material and having good integrity with softness. The dry laminated fibrous structure of the present invention can be used as an absorbent structure for absorbing a fluid, and preferably further has the ability to suppress odor associated with the absorbed fluid.

It is surprisingly known that thermoplastic polymer materials in finely separated form, preferably in particulate or powder form, can be effectively distributed between the particulate material and at least partially between the fibers of the dry laminated web. The resulting heat treatment melts the thermoplastic polymer material and thus reduces the effectiveness of the particulate material itself due to the very small dimensions of the thermoplastic particulate in the web, for example between the fiber and the particulate material in which the thermoplastic polymer material in finely separated form is distributed. Create a framework of individual join points without substantially modifying them. The use of the thermoplastic polymer material in finely separated form may be combined with conventional latex bonds (eg, thermoplastic powders preferably bind the inside of the dry laminated web), while adding a reduced amount of latex Stabilize the outer surface of the dry laminated web. In a variant embodiment, the dry laminated web may be completely joined by a thermoplastic polymer material in finely divided form that is uniformly dispersed within the entire web and then melted by heat treatment.

Summary of the Invention

The present invention relates to a dry laminated fibrous structure, the dry laminated fibrous structure comprising a dry laminated fibrous web having a first surface and a second surface aligned approximately opposite the first surface and particulate material distributed within the web. do. The dry laminated fibrous structure further comprises a thermoplastic polymer material in finely divided form distributed therein for bonding the particulate material to the fibers of the dry laminated fibrous web.

BACKGROUND OF THE INVENTION The present invention relates to dry laminated fibrous structures, preferably for absorbing aqueous fluids and / or for suppressing odors. The structure includes a dry laminated fibrous web and a particulate material distributed within the web and is bonded by a thermoplastic polymer material distributed therein. In particular, the structure is suitable for use as a disposable absorbent article.

Although the present application is terminated by the claims that clearly point out the invention and claim the rights in detail, the invention may be better understood by reference to the detailed description in conjunction with the accompanying drawings.

1 is a schematic partial side view of an apparatus for producing a fibrous structure according to the present invention;

2 is an enlarged cross-sectional view of the fibrous structure according to the present invention;

3 is a schematic partial side view of an apparatus for producing a variant embodiment of the fibrous structure according to the present invention;

4 is an enlarged cross-sectional view of a modified embodiment of the fibrous structure according to the present invention.

The present invention preferably relates to a dry laminated fibrous structure intended to absorb aqueous liquids and / or suppress odors. This structure consists of a dry laminated fibrous web comprising particulate material and is bound by thermoplastic polymer material dispersed therein in finely divided form. In a preferred embodiment, the structure of the invention is provided in an absorbent article, preferably in an absorbent structure that is intended to absorb and retain various body liquids. Absorbent products, in particular disposable absorbent products, absorb and retain various body fluids (e.g. vaginal discharge, menstrual fluid, sweat and / or urine) worn by the user in proximity to the body and discharged from the body and disposed of after one use Refers to products such as sanitary napkins, disposable diapers, and incontinence pads.

As used herein, the term "use" refers to a time period that begins when an absorbent product is in direct contact with a user's body.

In a preferred embodiment of the invention, the dry laminated fibrous structure according to the invention may be integrally formed with the absorbent core of the disposable absorbent article, or these structures may be included inside the core as part of the absorbent core, or in all cases These structures may constitute an element of a disposable absorbent article, for example, as absorbing body fluids, suppressing odors, or both functioning.

For example, disposable absorbent articles, such as sanitary napkins, panty liners, incontinence pads, or diapers, include liquid permeable topsheets, liquid impermeable backsheets that may selectively permeate water vapor and / or gases, and It includes an absorbent core positioned between the backsheet.

The dry laminated fibrous structure of the present invention comprises particulate matter dispersed in a web that is capable of absorbing aqueous liquids and / or inhibiting odors, such as, for example, odors associated with the absorbed liquid. Preferably, the particulate material comprises absorbent gelling material and odor inhibiting means, all of which are in particulate form.

The fibrous structure of the present invention can be manufactured using conventional apparatus designed with a dry lamination method, and the present invention is described below based on the air layer structure, but it should be understood that other dry lamination methods such as carding are also applicable.

The present invention relates in particular to an air layer fibrous structure capable of absorbing an aqueous liquid, which is a body liquid, and suppressing odor associated with the absorbed liquid, and is considered to be provided as an absorbent structure in disposable absorbent articles such as sanitary napkins.

1 is a simplified schematic diagram of a preferred embodiment of making the fibrous structure of the present invention. According to the present invention, an air forming system, denoted by reference numeral 10, is mounted on a roller 16 and is disposed transversely on a continuous forming screen 14 driven by a suitable motor (not shown). 12), wherein the vacuum means or suction box 18 is located below the screen. In conventional air forming systems, upstream of the distributor unit is a defibrator or feeder (not shown), such as a hammer mill or a Rando-Feeder, where bales, wraps, etc. (laps) and the like are fiberized, and the fibers may also be cleaned and / or kneaded as necessary or desired depending on the type of fiber used, the blend of fiber used and the final product to be produced. For example, wood pulp fibers may be kneaded with synthetic fibers and applied as kneaded by a single dispenser, or other fibers may be transferred separately to the screen by different dispensers to form individual plies or layers.

The porous forming screen 14 extends substantially co-extender with the distributor, and the suction box 18 below the screen sucks the air stream down and transports the fibers to the surface of the screen to form a fly or loose web 22. . In the step of this method, the web is almost integral and the vacuum means is maintained as a loose fibrous web on the screen. The web 22 has a first surface 6 in contact with the dispenser and a second screen 8 opposite the first surface 6 and in contact with the forming screen 14.

It should be understood that the system may be modified to control the composition and thickness of the final product. For example, a dispenser unit may include a number of individual dispensers, while FIG. 1 schematically shows two dispensers 12A and 12B, although the number and specific arrangement of such dispensers may vary in machine speed, performance, fiber type. And may be changed or modified depending on factors such as the final product required.

The web 22 formed on the screen 14 is provided with particulate material therein. In a preferred embodiment, the particulate material comprises a mixture of absorbent gelling material and odor control means, all in particulate or powder form. In the preferred embodiment shown in FIG. 1, an input unit or feed hopper 24 comprising particulate material is located in the middle of the distributor unit, ie between the distributors 12A and 12B. In the embodiment shown in Figure 1, the dosing unit 240 houses different particulate matters from the supply containers 25, 26, each containing absorbent gelling material in particulate form and odor suppressing means, respectively. 24 provides a particulate material of a homogeneous mixture.

Thermoplastic polymer material, preferably in finely divided form in powder form, is added to the fibrous web 22; In a preferred embodiment, the thermoplastic polymer material in powder form is fed from the container 27 to the input unit 24 and mixed homogeneously with the particulate material coming from the containers 25, 26.

In this method, particulate material comprising the thermoplastic polymer material in powder form is placed between the plies of fibers laminated by each distributor. That is, the particulate material and the thermoplastic polymer material are discharged from the hopper 24 into the moving layer of fibers lying down by the dispenser 12A, and the plies of fibers lying down by the dispenser 12B are in the particulate material phase. Will be placed in. However, the plies are relatively porous, so that the particulate material and the thermoplastic polymer material tend to be distributed in somewhat adjacent plies. Thus, the resulting fibrous web 22 includes areas of web 22 in which the fibers comprise a lower percentage as compared to the particulate material and thermoplastic polymer material, including particulate material and thermoplastic polymer material concentrated in the middle of the thickness thereof. Form. If desired, the particulate material is mixed with the fibers in one or more dispensers, such as dispensers 12A and 12B, to form a web in which the particulate material is intermixed with one or more fibrous plies of the web. However, the particulate material with the thermoplastic particulate material is distributed within the thickness of the web 22 between the first surface 6 and the second surface 8.

The web 22 concentrated on the forming screen 14 has a very low integrity and requires stabilization. In the embodiment shown in FIG. 1, the web is subjected to a first stabilization step by thermal treatment at the bonding station 28. The particulate material and fibers of the web 22 contained in the particulate material and at least partially contained in the two plies are mixed with the particulate material composed of the absorbent gelling material and the malodor suppression means by applying heat and optionally applying a regulating pressure. The thermoplastic polymer material in powdered form.

The particulate material and the adhesive in the fiber are achieved by melting individual particulates of the thermoplastic polymeric material in powder form; When melted, the thermoplastic polymer material forms "bridges" that directly bond the particulate material with the fibers.

The total surface area of the point of adhesion represents a small fraction of the surface area of the particulate material and the fibers involved in the adhesion, and therefore the properties remain almost unchanged. The preferred thermoplastic polymer material in powder form may be distributed homogeneously in the particulate material, such that the fibers contained therein may provide a web 22 that is effectively bonded in the portion benefited by the distribution of the thermoplastic polymer material itself. Can be; In the embodiment of the invention achieved by the apparatus of FIG. 1, this is a web 22 composed mainly of particulate material having a lower percentage of fibers between the first surface 6 and the second surface 8. Corresponds to the area of.

Preferably, the absorbent gelling material distributed in particulate form can be made of an inorganic or organic material, such as a crosslinked polymer, all of which are known in the art.

The malodor suppression means may be any suitable malodor suppressant known in the art or any mixture thereof, and may consist, for example, of particulates of zeolite and silica.

The average dimension of the particulate material, given as the weight average of the smallest dimension of the individual particulates, may be between 50 microns and 1500 microns, preferably between 100 microns and 800 microns.

Finely divided thermoplastic polymer materials, such as, for example, powder forms, have the purpose of adhering the particulate material and at least partially dry laminated absorbent structures together with melting and forming discrete spaced adhesion points in the particulate and fibers. . The thermoplastic polymeric material can also be used in other finely divided forms, for example in the form of fine fibers.

As mentioned above, the bridges that form these bond points may include the particulate material and fibers of the web 22.

The amount of finely divided thermoplastic polymer material provided in the web 22 may be between 5 g / m 2 and 180 g / m 2.

The finely divided thermoplastic polymer material can be preferably melted at a temperature that does not interfere with the properties of the other components of the absorbent structure, ie the fiber and particulate material, and in preferred embodiments comprises absorbent gelling material and odor suppressing means. . Thus, the thermoplastic polymer material must have fluidity so that the required adhesion can be achieved rapidly.

This preferred property is a melt flow index (MFI) evaluated by ASTM method D 1238-85 under conditions 190 / 2.16 of at least 25 g / 10 min, preferably at least 40 g / min, more preferably at least 60 g / 10 min. It can be achieved by thermoplastic polymer material in finely divided form with).

If the fibers of the dry formed fibrous structure are short cellulose fibers, a powder of high density polyethylene having a maximum dimension of about 400 microns fine particles, a melt flow index of about 50 g / 10 min, and an amount between 12 g / m 2 and 90 g / m 2 Preference is given to using thermoplastic polymeric materials consisting of:

According to the embodiment of the invention shown in FIG. 1, the web 22 can be adhered on one surface or preferably both surfaces 6, 8 by applying a latex compound. The web 22 is first compressed between compression rollers (not shown), which can be heated to densify the web but this step is optional. This step of densification improves the penetration of latex into the web, and the degree or degree of densification varies depending on factors such as the amount of malodor inhibiting particles, the basis weight of the web, the required degree of penetration of the latex into the web, and the end product desired. Can be.

After passing through the adhesion station 28 and (optional) compression rollers, the web is subjected to suitable dispensing means such as spray nozzles, doctor blades, roller applicators, etc., in which the latex binder is applied to the first surface 6 of the web 22. Are transferred to 30. The vacuum applied by the dispensing means and the suction box 19 located under the screen 14 serves to pull the latex into the web. The dispensing means or applicator is essentially co-extended with the width of the web, and preferably a substantially constant coating is applied to the web surface. However, the latex can be applied as a non-uniform random or patterned coating, and since the latex is water based, it functions as a binder when it diffuses through the web and cures.

The latex when cured imparts integrity to the web and therefore requires some penetration of the latex. The extent or extent of the latex penetration into the web is controlled by controlling the amount of latex applied and by controlling the vacuum applied to the web when the vacuum draws the latex into the web. The extent or extent of this penetration is not limited to the surface of the web 22 since the portion of the web 22 comprising the particulate material in the middle of the surfaces 6, 8 is already joined by the thermoplastic polymer material, Thus all possible negative interference between the latex compound and the particulate material is avoided. The amount of latex compound also maintains this range without imparting absorbency and softness of the fibrous web 22.

Typically the latex is applied as an aqueous emulsion and may be a thermoset plastic. To activate the latex, the latex emulsion comprises a suitable curing agent and crosslinker, and after the web is coated, the latex is cured to effect crosslinking. In particular, curing is achieved by passing the coated web through a hot air oven or air dryer 32 and typically the temperature ranges from 100 ° C. to 260 ° C., but this is the specific form, latex or crosslinking of the latex resin used. It depends on the binder, the amount of latex, the thickness of the web, the degree of vacuum and the machining speed.

It is also desirable to coat the second surface 8 of the web 22 with latex, which is on the second screen 34 where the web 22 operates about the pulleys 191, 192, 193, 194. Easily achieved by the dispensing means 36 when conveyed. The second dispensing means 36 comprises a suction box 37. This second latex coating is similarly cured by passing the web through the second oven 38 within approximately the same temperature range.

The final absorbent structure 40 exiting the final oven has sufficient integrity and can be cut, rolled, packaged, or the like.

An absorbent structure 40 manufactured according to the method described above is shown in FIG. The absorbent structure 40 includes irregularly distributed fibers 46, such as wood pulp fibers, and the particulate material 42 is distributed in the absorbent structure. The thermoplastic polymer material 48 in powder form is mainly distributed in the particulate material 42 and performs adhesion of the particulate material and at least a portion of the fibers of the absorbent structure 40, ie, the fiber in contact with the thermoplastic polymer material. The particulate material is more concentrated in the middle region of the absorbent structure, but some of the particulates enter other portions of the absorbent structure. The first and second surfaces 6, 8 of the absorbent web 22 support the latex coating 50, which is shaded in the figure, which penetrates or penetrates the absorbent structure to some extent and partially covers part of the fiber. Cover with. As mentioned above, this penetration is controlled so as not to impart the properties of the particulate matter.

The fibrous structure of the present invention exhibits relatively high tensile strength and is soft, strong and absorbent. Preferred absorbent fibrous structures of this type are preferred to have a relatively small volume because they are thinner but higher absorbent than densified absorbent structures as compared to similar structures that contain approximately the same absorbent performance but have a larger volume. Because the volume is reduced accordingly. The reduction in volume, which means reducing the volume occupied by the absorbent fibrous structure without significantly sacrificing other necessary properties, is important from the standpoint of manufacture, storage and packaging. Thus, in the product of the present invention, the basis weight may range from about 50 g / m 2 to 600 g / m 2, preferably about 75 g / m 2 to 400 g / m 2, more preferably 250 g / m 2 to 350 g / m 2. Absorbent structures having a basis weight of less than about 50 g / m 2 are difficult to manufacture, and these absorbent structures lack the required strength. If the basis weight exceeds the upper limit, the product is too strong and therefore not useful for application.

All various types of fibers, including blends or mixtures, can be used in the fibrous structure of the present invention. The fibers can be cellulose, modified cellulose or synthetic and include fibers such as wood pulp, rayon, cotton, cellulose acetate, polyester, polyethylene, polypropylene, nylon and the like. Fibrous structures, preferably comprising cellulose fibers such as wood pulp fibers, are particularly useful as absorbent structures in products such as sanitary napkins, disposable diapers or handkerchiefs, because cellulose is liquid absorbent and thus the entire structure of the structure. This is because the absorbency is improved. Also products of this type, such as absorbent fibrous structures, utilize a mixture of cellulose and synthetic fibers comprising from about 65% to 95% by weight of cellulose fibers and more preferably up to about 20% by weight of synthetic fibers. It is advantageous. Synthetic fibers, which can be provided in any length, including staple lengths, can improve the strength of the structure. In addition, synthetic fibers can be treated to make them hydrophilic so as not to reduce the absorbent performance of the desired absorbent fibrous structure.

Preferred fibrous structures described so far include hydrophilic fibers that are substantially absorbent towards aqueous liquids, which are useful as absorbent structures in disposable absorbent articles. The dry laminated fibrous structure according to the invention may also comprise hydrophobic fibers, such as only synthetic fibers. Such a structure may include only malodor suppression means as particulate matter, and thus suppresses malodor without absorbing and retaining liquid. Structures of this type can be included in disposable absorbent articles as a liquid containment and delivery layer, for example a capture layer comprised between the topsheet and the absorbent core, which captures body fluid quickly and delivers it to the absorbent core. At the same time, the odor suppression effect to the liquid can be performed. The structure according to the invention, which consists solely of hydrophobic synthetic fibers, may also be useful in different applications such as, for example, filter media.

Thus, the form of the fiber and particulate blend may vary depending on the final product. In addition to the applications described above, the absorbent structures of the present invention can be suitably used for incontinence pads, diaper cores, diaper inserts and medical and wound bands to provide absorbent performance and / or odor suppression.

Preferably, the absorbent gelling material forming at least a portion of the particulate material comprised of the dry laminated absorbent structure of the present invention may be one of the known materials (sometimes referred to as "superabsorbents") widely used in absorbent articles. AGM is a substance with liquid absorption capability. Such materials form hydrogels upon contact with water (eg, urine, blood, etc.). One highly preferred form of hydrogel forming absorbent gelling material is based on polyacids, in particular polyacrylic acid. Hydrogel forming polymer materials of this type are those which absorb such liquids upon contact with liquids (ie, liquids) such as water or body liquids and thereby form hydrogels. Such preferred absorbent gelling materials are generally prepared from polymerizable unsaturated acid containing monomers and include polymeric materials that are substantially insoluble in water, lightly crosslinked, partially neutralized, and form hydrogels. In such materials, the polymeric component formed from unsaturated, acid-containing monomers may comprise a total gelling agent or may be fused with other types of polymeric moieties such as starch or cellulose. Acrylic acid fused with starch material is this latter form. Accordingly, preferred absorbent gelling materials include hydrolyzed acrylonitrile fused starch, acrylic acid fused starch, polyacrylates, male anhydride based copolymers and combinations thereof. In particular, preferred absorbent gelling materials are polyacrylate and acrylic acid fused starch.

Preferably, the malodor suppressing means included in the fibrous structure of the present invention may include various malodor inhibitors to suppress unpleasant malodors such as malodors associated with the absorbed liquid when the fibrous structure is a liquid absorbent structure.

In a preferred use as an absorbent core in disposable absorbent articles, the absorbent structure of the present invention is to absorb body fluids.

Various body liquids include odorous chemical components, including sulfur containing components such as aperiodic and periodic menstruation, aldehydes, fatty acids and sulfides. For example, menstrual drainage and sanitary napkins used may include odorous chemical components such as trimethylamine, pyridine, peraldehyde, isobalic acid and methyl mercapic acid. The particular malodorous component to be absorbed by the various absorbent products varies depending on the person wearing the absorbent product and the type of absorbed body fluids such as urine, menstrual fluid, vaginal discharge, sweat, salt, and the like. In women's pads, such as sanitary napkins and panty liners, the time of wearing the product, the amount of liquid absorbed, and the odor that can be emitted by the absorbent product are determined by the pad being exposed to other body fluids.

All suitable malodor inhibitors known in the art are provided in the dry laminated fibrous structure of the present invention to suppress odors, such as odors associated with absorbed body liquids, when the dry laminated fibrous structure is an absorbent structure provided in a disposable absorbent article. Provides a structure that has the advantage of

Suitable odor inhibitors that may be used in the practice of the present invention may be water soluble antimicrobial compounds. Such compounds include, for example, halogenated phenylene compounds (see US Pat. No. 3,093,546), periodic acid (see US Pat. No. 3,804,094), various copper compounds, in particular copper acetate (see US Pat. No. 4,385,632), cetyl chloride Various tetravalent ammonium salts known to have antimicrobial properties such as pyridinium and the like. Optionally, the antimicrobial compound can be used in combination with various particulate materials that release the antimicrobial agent at the time of use and when moisture is present. Zeolite materials, such as sterilized geolites, can be advantageously used in the practice of the present invention because various bactericidal cations such as copper, silver and zinc are absorbed therein and on them (see US Pat. No. 4,525,410). In a preferred mode, the malodor inhibitor comprises chlorophyll particles, activated carbon granules, charcoal, ion exchange resins (see Japanese Patent Application 87-19865), activated alumina, and known "molecular sieves" of types A and X. (molecular sieve) "is a particulate odor absorbing material that is insoluble in water, such as an absorbent geolite material, including a zeolite, which is manufactured by Union Carbide Corporation and UP and manufactured by ABSCENTS ( Commercially available as a white powder sold under the trademark and having a particle size range of 3 to 5 microns.

In a known mode, the malodor inhibitor comprises chlorophyll particles, activated carbon granules, charcoal, ion exchange resins (see Japanese Patent Application No. 87-19865), activated alumina, and known "molecule upon It may be a particulate odor absorbent material that is insoluble in water, such as an absorbent geolite material including Eve "geolite, which is manufactured by Union Carbide Corporation and UP, and is registered with ABSCENTS (registered). Commercially available as a white powder, sold under the trademark " and having a particle size range of 3 to 5 microns.

In addition, odor inhibitors used in the present invention may include other compounds such as cyclodextrins, chelating reagents, parabens, chitin, pH buffer materials, silica gels, clays, diatomaceous earth, polystyrene derivatives, starches and the like. Particular preference is given to chelating reagents, for example in European patent applications 96109178.2 and 96109179.0, filed June 7, 1996. Some partially neutralized hydrogel-forming absorbent gelling materials such as polyacrylate gelling materials and acrylate fused starch gelling materials can be used or in combination with other odor suppressing means.

Other odor inhibitors include ascorbic acid, stearic acid, boric acid, maleic acid polymers, acid compounds such as maronic acid, maleic acid, polyacrylic acid, monopotassium phosphoric acid, or carbonates, divalent carbonates, phosphates as disclosed in US Pat. No. 5,037,412. Basic compounds such as divalent phosphates, sulfates, divalent sulfates, boron salts and mixtures thereof or combinations of boric acid and sodium tetravalent borate disclosed in WO 94/25077.

The malodor suppression means which can be preferably used in the practice of the present invention should not be understood simply as being added to the malodor suppressant, ie, the fibrous structure. Rather, malodor suppression means include all combinations of malodor inhibitors and optionally other substances such as binders. Thus, for example, aggregates of binders and other malodor inhibitors can be used, such as aggregates of zeolites and silica in the form of particles as disclosed in European Patent Application No. 96109175.8, filed June 7, 1996. Malodor inhibitors, on the other hand, are certain malodor inhibiting compounds.

Preferably the malodor inhibitor is used in particulate form in the present invention. Particularly preferred are silica gels, absorbent gelling materials and combinations thereof, such as odor suppressing means disclosed in WO 95/26207 and European Patent Applications 96109177.4, 96109173.3, 96109174.1 and 96109176.6. Odor suppression means comprising zeolite in the form of water and silica.

For example, the preferred malodor inhibiting means may be a combination of fine particles of silica gel, zeolite and absorbent gelling material. The weight ratio of absorbent gelling material to silica to zeolite ranges from 1: 5: 1 to 1: 1: 5, preferably from 1: 3: 1 to 1: 1: 3, more preferably from 1: 1: 1 to 1: 1.5: 1.5.

The malodor suppressing material is provided in the fibrous structure according to the present invention, and the amount thereof ranges from 20 g / m 2 to 400 g / m 2, preferably 100 g / m 2 to 300 g / m 2, more preferably 150 g based on the total surface area of the fibrous structure. / M 2 to 250 g / m 2. Preferably, the fibrous structure of the present invention may comprise from 20% to 80% by weight of the liquid containment means. The weight of the malodor inhibiting means that can be practically used in the various fibrous structures to be formed for other purposes can be readily determined by a skilled person depending on the intended size and shape of the fibrous structure and its intended use.

Latexes are typically applied as aqueous emulsions or dispersants comprising about 45% to 65% solids, and these materials are readily available from some manufacturers. Since latex emulsions can be mixed with water, they may be further diluted before application to the web if necessary. In addition, these latex compounds are thermoset and they may contain small amounts of known suitable binders such as N-methylacrylamide as known chemical agents for this purpose so as to be crosslinked. All forms known in the art that are suitable for the fibrous structure of the present invention can be used, especially because they exhibit at least partially desirable malodor suppression performance of the fibrous structure before the user feels uncomfortable and even prior to their intended use. It is preferable not to generate odor that can be felt after curing. Useful latexes are chemical groups, these include vinyl acetate and acrylic ester copolymers, ethylene vinyl acetate copolymers, styrene butadiene carbosylate copolymers and polyacrylonitriles, especially for example air products, inks, hycars ( "Airbond, Airflex and Vinac" manufactured by Air Products, Inc., Hycar), "Geon" of Goodrich Chemical Co., and H.C. ratio. It is sold as "Fulatex" by H. B. Fuller Company. The amount of latex used in the absorbent structure should not be such that the effective malodor suppression performance of the malodor suppression means and also the absorbent performance of the hydrophilic fibers are not substantially reduced or blocked or the structure is hardened to render the structure unusable. The amount of latex ranges from about 5% to 30% by weight, preferably about 10% to 20% by weight of the structure.

The fibrous structures produced according to the invention exhibit good integrity due to the bonding carried out by the thermoplastic polymer material contained in the structure in a finely divided form and, optionally, with a latex coating, and have a pronounced absorption or odor suppressing performance or more. Preferably they have both performances because the particulate material contained in the fibrous web is affected by the bonding means, i.e. by the thermoplastic polymer material in finely divided form and by latex coating to the minimum extent possible. to be. If a latex binder is used, the depth at which the latex penetrates into the fibrous web can be controlled by selecting an amount applied to the web and by a suction box positioned corresponding to the dispensing means.

FIG. 3 is a simplified schematic diagram of an apparatus for manufacturing a dry laminated absorbent structure 59 of another preferred embodiment according to the present invention, such as for example the absorbent structure shown in FIG. 4.

The device of FIG. 3 is similar to the device shown in FIG. 1, with the same reference numerals representing the corresponding parts, but in this case the latex coating and hardening portions are missing, because the entire bond of the structure is fine with the web. Because it is carried out by a thermoplastic polymer material in a well-divided form.

As shown in FIG. 3, the thermoplastic polymer material, preferably in powder form, contained in the container 27 is fed to the feeder 24 and to the dispensers 12A and 12B. Thus, the thermoplastic polymeric material is mixed with the particulate material and into a fibrous homogeneous forming fibrous ply.

During the subsequent joining stage performed at the joining station 28, the entire dry laminate structure 59 is a thermoplastic that bonds the fibers of the web 22 with the particulate material contained in the middle of the first and second surfaces 6,8. Thermally stabilize to full thickness by melting the powder of polymeric material.

Referring to FIG. 4, the dry laminated absorbent structure 59 is composed of a mixture of fibers and an absorbent gelling material and odor suppressing means inserted into the web, but is concentrated in the middle of the thickness portion of the web 22. It includes. The thermoplastic polymeric material 63 in powder form is homogeneously dispersed within the entire fibrous web forming the dry laminated absorbent structure 59.

In another embodiment of the invention, the absorbent gelling material or odor suppressing means may be included in the absorbent structure in a different form than the particulate form, ie a fibrous absorbent gelling material may be used or in the form of a solution sprayed onto the absorbent structure. Malodor suppression means is provided so that the particulate matter is included in the absorbent structure. For example, a suitable solution may be sprayed onto the first fibrous ply layer below the dispenser 12A in the device shown in FIG. 1 or on the first surface 6 of the web 22 in FIG. 3 or a combination thereof. The malodor suppression means is distributed in the form of particles by the hopper 24 in the web 22.

In another embodiment of the invention, not shown, the latex coating is also applied to the first ply of the fibrous web and then cured before the particulate material is applied onto the surface to which the particulate material is to be dispensed.

One of the plies of fibrous web, such as the second ply of the web of FIG. 3, may be replaced with a nonwoven layer or polymer film in another embodiment. In the latter case, the polymer film should be applied to the web after the bonding station 28 to prevent the temperature in the bonding station from melting the polymer film. Structures of this type constitute an absorbent element of a disposable absorbent article having an impermeable layer contained therein.

Claims (10)

Dry laminated fibrous structure, preferably dry laminated absorbent fibrous structure, the structure comprising a first surface and a second surface aligned approximately opposite of the first surface, wherein the dry comprises a particulate material distributed in the web In the laminated fibrous structure, Further comprising a thermoplastic polymeric material distributed therein in finely divided form for bonding the particulate material to the fibers of the dry laminated fibrous web. Dry laminated fibrous structure. The method of claim 1, The particulate material is characterized in that it comprises an absorbent gelling material (absorbent gelling material) Dry laminated fibrous structure. The method according to claim 1 or 2, The particulate matter comprises odor suppressing means Dry laminated fibrous structure. The method according to any one of claims 1 to 3, Wherein said particulate material is distributed within the thickness of said dry laminated fibrous web between said first surface and said second surface. Dry laminated fibrous structure. The method according to any one of claims 1 to 4, Said thermoplastic polymer material being in particulate or powder form Dry laminated fibrous structure. The method according to any one of claims 1 to 5, The thermoplastic polymer material is mixed with the particulate material Dry laminated fibrous structure. The method according to any one of claims 1 to 6, The dry laminated fibrous structure further comprises a latex coating on at least one of the first surface or the second surface of the fibrous web. Dry laminated fibrous structure. The method according to any one of claims 1 to 7, Wherein said thermoplastic polymeric material further provides bonding of said dry laminated fibrous web. Dry laminated fibrous structure. The method according to any one of claims 1 to 8, The dry laminated fibrous structure is characterized in that the air layer Dry laminated fibrous structure. Disposable absorbent article comprising the dry laminated fibrous structure according to claim 1.