Patent Description:
Nonwoven structures are important in a wide range of consumer products, such as absorbent articles including baby diapers, adult incontinence products, sanitary napkins, wipes, and the like. Such nonwoven structures can include various layers and/or components, configured to direct and control the acquisition and retention of liquids. Each of these layers and/or components can include a specific fibrous network that provides the desired functionality.

Pre-moistened mopping cloths and wipes are known in the art, however, their material compositions can run out of stored liquid relatively quickly and therefore become unusable in an unacceptably short period of time and/or after cleaning a relatively small area. This causes the consumer to buy and use more pre-moistened cleaning products. Additionally, single use pre-moistened cleaning materials are inefficient when scrubbing action is required which makes consumers rely on other or additional products. <CIT> discloses an absorbent, non-linting nonwoven web. <CIT> discloses the incorporation of a hydrophile in fibrous webs to enhance absorbency.

<CIT> and <CIT> each disclose absorbent structures comprising a nonwoven material obtained by air-laying.

Thus, there remains a need in the art for nonwoven materials that can absorb and gradually release liquid in order to enable a larger surface area to be cleaned. In addition, there remains a need for pre-moistened cleaning materials having improved scrubbing and scouring properties. The disclosed subject matter addresses these and other needs.

One aspect of the invention relates to a unitary airlaid nonwoven material comprising three layers of fibers, the first layer being the top layer, the second layer being the middle layer, and the third layer being the bottom layer, wherein the first layer comprises synthetic fibers, the second layer comprises cellulose fibers and synthetic fibers, and the third layer comprises cellulose fibers and a high core bicomponent fiber having a core to sheath ratio that exceeds <NUM>:<NUM> in that the core forms more than <NUM>% by weight of the high core bicomponent fiber, wherein hardwood bonded natural cellulosic fibers having a coarseness in a range of from <NUM>/<NUM> to <NUM>/<NUM> are contained in the second layer or the third layer, wherein the synthetic fibers of the first layer comprise bicomponent fibers in an eccentric configuration, and wherein the high core bicomponent fiber comprises a polyethylene-based sheath and a core comprising a polymer having a melting point above about <NUM> and higher density than the polyethylene sheet, and wherein the synthetic fibers of the second layer comprise low core bicomponent fibers wherein the core forms less than <NUM>% and <NUM>% or more by weight of the low core bicomponent fiber.

The presently disclosed subject matter provides for nonwoven materials comprising bonded natural cellulosic fibers characterized by high capillary action and bonded synthetic fibers. The bonded natural cellulosic fibers can include, for example, mono-component polyester fibers or bicomponent binder fibers. The nonwoven materials of the presently disclosed subject matter provide relatively high liquid retention and a metered release of liquid.

In certain non-limiting embodiments, the bonded natural cellulosic fibers can have a coarseness of about <NUM>/<NUM>.

In certain non-limiting embodiments, the bonded natural cellulosic fibers can have a Kajaani weighted average length of about <NUM> or less.

In certain non-limiting embodiments, the bonded natural cellulosic fibers can include eucalyptus pulp.

In certain non-limiting embodiments, the unitary airlaid nonwoven material can further include a layer of cellulose fibers.

In certain non-limiting embodiments, at least one layer of fibers can be coated on at least a portion of its surface with a binder.

In certain non-limiting embodiments, at least one layer of fibers can be coated on at least a portion of its surface with an adhesive.

In certain non-limiting embodiments, the nonwoven material can further include one layer including synthetic fibers.

In certain non-limiting embodiments, the nonwoven material can further include a cleaning formulation.

In certain non-limiting embodiments, the cleaning formulation can be aqueous based.

The unitary airlaid nonwoven material according to the present invention includes three layers of fibers. The first layer includes synthetic fibers. The second layer includes cellulose fibers and synthetic fibers. The third layer includes cellulose fibers and synthetic fibers. The second layer can be coated on at least a portion of its surface with a binder. The first layer can be coated on at least a portion of its surface with an adhesive.

The foregoing has outlined broadly the features and technical advantages of the present application in order that the detailed description that follows may be better understood.

Additional features and advantages of the application will be described hereinafter which form the subject of the claims of the application. It should be appreciated by those skilled in the art that the conception and specific embodiment disclosed may be readily utilized as a basis for modifying or designing other structures for carrying out the same purpose of the present application. It should also be realized by those skilled in the art that such equivalent constructions do not depart from the scope of the application as set forth in the appended claims. The novel features which are believed to be characteristic of the application, both as to its organization and method of operation, together with further objects and advantages will be better understood from the following description.

The presently disclosed subject matter provides for multi-layer unitary absorbent nonwoven materials, which can be used for variety of applications. In particular, the nonwoven materials described herein absorb and store liquids and can be used as absorbent materials for cleaning liquids from hard surfaces. Alternatively, the nonwoven materials can be used in pre-moistened cleaning materials such as pre-moistened wipes and mopping cloths since the nonwoven materials can absorb relatively high amounts of liquid and further provide a metered release of the liquid. The presently disclosed subject matter also provides methods for making such nonwoven materials. These and other aspects of the disclosed subject matter are discussed more in the detailed description and examples.

The terms used in this specification generally have their ordinary meanings in the art, within the context of this subject matter and in the specific context where each term is used. Certain terms are defined below to provide additional guidance in describing the compositions and methods of the disclosed subject matter and how to make and use them.

As used in the specification and the appended claims, the singular forms "a," "an" and "the" include plural referents unless the context clearly dictates otherwise. Thus, for example, reference to "a compound" includes mixtures of compounds.

The term "about" or "approximately" means within an acceptable error range for the particular value as determined by one of ordinary skill in the art, which will depend in part on how the value is measured or determined, i.e., the limitations of the measurement system. For example, "about" can mean within <NUM> or more than <NUM> standard deviations, per the practice in the art. Alternatively, "about" can mean a range of up to <NUM>%, preferably up to <NUM>%, more preferably up to <NUM>%, and more preferably still up to <NUM>% of a given value. Alternatively, particularly with respect to systems or processes, the term can mean within an order of magnitude, preferably within <NUM>-fold, and more preferably within <NUM>-fold, of a value.

As used herein, the term "weight percent" is meant to refer to either (i) the quantity by weight of a constituent/component in the material as a percentage of the weight of a layer of the material; or (ii) to the quantity by weight of a constituent/component in the material as a percentage of the weight of the final nonwoven material or product.

The term "basis weight" as used herein refers to the quantity by weight of a compound over a given area. Examples of the units of measure include grams per square meter as identified by the acronym "gsm".

As used herein, a "nonwoven" refers to a class of material, including but not limited to textiles or plastics. Nonwovens are sheet or web structures made of fiber, filaments, molten plastic, or plastic films bonded together mechanically, thermally, or chemically. A nonwoven is a fabric made directly from a web of fiber, without the yarn preparation necessary for weaving or knitting. In a nonwoven, the assembly of fibers is held together by one or more of the following: (<NUM>) by mechanical interlocking in a random web or mat; (<NUM>) by fusing of the fibers, as in the case of thermoplastic fibers; or (<NUM>) by bonding with a cementing medium such as a natural or synthetic resin or binder.

As used herein, the term "cellulose" or "cellulosic" includes any material having cellulose as a major constituent, and specifically, comprising at least <NUM> percent by weight cellulose or a cellulose derivative. Thus, the term includes cotton, typical wood pulps, cellulose acetate, rayon, thermochemical wood pulp, chemical wood pulp, debonded chemical wood pulp, milkweed floss, microcrystalline cellulose, microfibrillated cellulose, and the like.

As used herein, the term "fiber" or "fibrous" refers to a particulate material wherein the length to diameter ratio of such particulate material is greater than about <NUM>. Conversely, a "nonfiber" or "nonfibrous" material is meant to refer to a particulate material wherein the length to diameter ratio of such particulate matter is about <NUM> or less.

As used herein, the phrase "high core bicomponent fibers" refers to bicomponent fibers having a core-sheath configuration, wherein the core comprises more than <NUM>% of the fiber, by weight. Equivalently states, it can be said that the high core bicomponent fibers have a core to sheath ratio of greater than <NUM>:<NUM>.

As used herein, the term "metered release" refers to slowed migration of a liquid in a pre-moistened wipe, resulting in gradual release of liquids from multi-layer nonwoven structures.

As used herein, the term "Kajaani weighted average length" refers to fiber length determined by Kajaani fiber length apparatus.

As used herein, the term "capillary action" refers to the ability of a liquid to flow in narrow spaces without the assistance of, or even in opposition to, external forces such as gravity. Section <NUM>. <NUM> "Surface Properties and Capillary Tension" of the Dutkiewicz, J. , Nonwoven Structures for Absorption of Body Fluids, (<NUM>) ISBN <NUM>-<NUM>-<NUM>-<NUM> (published by Edana - Brussels, Belgium) publication provides additional disclosure with reference to capillary action.

As used herein the terms "coarseness" or "fiber coarseness" refer to weight per fiber length and can be expressed in units of mg/<NUM>. Coarseness depends on fiber diameter, cell wall thickness, cell wall density and fiber cross section. In general, thinner wood fibers such as hardwood fibers are characterized by lower coarseness whereas thicker wood fibers such as softwood fibers are characterized by higher coarseness.

The nonwoven materials of the presently disclosed subject matter comprise synthetic fibers and cellulose fibers.

The presently disclosed subject matter contemplates the use of synthetic fibers. Non-limiting examples of synthetic fibers suitable for use in the present disclosure include fibers made from various polymers including, by way of example and not by limitation, acrylic polymers, polyamides (including, but not limited to, Nylon <NUM>, Nylon <NUM>/<NUM>, Nylon <NUM>, polyaspartic acid, polyglutamic acid), polyamines, polyimides, polyacrylics (including, but not limited to, polyacrylamide, polyacrylonitrile, esters of methacrylic acid and acrylic acid), polycarbonates (including, but not limited to, polybisphenol A carbonate, polypropylene carbonate), polydienes (including, but not limited to, polybutadiene, polyisoprene, polynorbomene), polyepoxides, polyesters (including, but not limited to, polyethylene terephthalate, polybutylene terephthalate, polytrimethylene terephthalate, polycaprolactone, polyglycolide, polylactide, polyhydroxybutyrate, polyhydroxyvalerate, polyethylene adipate, polybutylene adipate, polypropylene succinate), polyethers (including, but not limited to, polyethylene glycol (polyethylene oxide), polybutylene glycol, polypropylene oxide, polyoxymethylene (paraformaldehyde), polytetramethylene ether (polytetrahydrofuran), polyepichlorohydrin), polyfluorocarbons, formaldehyde polymers (including, but not limited to, urea-formaldehyde, melamine-formaldehyde, phenol formaldehyde), natural polymers (including, but not limited to, cellulosics, chitosans, lignins, waxes), polyolefins (including, but not limited to, polyethylene, polypropylene, polybutylene, polybutene, polyoctene), polyphenylenes (including, but not limited to, polyphenylene oxide, polyphenylene sulfide, polyphenylene ether sulfone), silicon containing polymers (including, but not limited to, polydimethyl siloxane, polycarbomethyl silane), polyurethanes, polyvinyls (including, but not limited to, polyvinyl butyral, polyvinyl alcohol, esters and ethers of polyvinyl alcohol, polyvinyl acetate, polystyrene, polymethylstyrene, polyvinyl chloride, polyvinyl pryrrolidone, polymethyl vinyl ether, polyethyl vinyl ether, polyvinyl methyl ketone), polyacetals, polyarylates, and copolymers (including, but not limited to, polyethylene-co-vinyl acetate, polyethylene-co-acrylic acid, polybutylene terephthalate-co-polyethylene terephthalate, polylauryllactam-block-polytetrahydrofuran), polybutylene succinate and polylactic acid based polymers, derivatives thereof, copolymers thereof, and the like, or combinations thereof. In certain embodiments, these polymer materials can be used in a monocomponent fiber. Alternatively, two or more polymer materials can be used together in a bicomponent fiber, e.g., a high core bicomponent fiber or a low core bicomponent fiber.

In In certain non-limiting embodiments, the synthetic fibers can comprise monocomponent fibers (i.e., single synthetic polymer or copolymer component in the fibers), bicomponent fibers (i.e., two synthetic polymer or copolymer components in the fibers), multicomponent fibers (i.e., more than two synthetic polymer or copolymer components in the fibers), or combinations thereof.

In certain non-limiting embodiments, the synthetic fibers can comprise monocomponent fibers, in which the monocomponent fibers can comprise polyethylene, polypropylene, polyester, polylactic acid (PLA), and the like, or combinations thereof.

In certain-nonlimiting embodiments, the synthetic fibers can comprise bicomponent fibers. Generally, bicomponent fibers can have a core and a sheath surrounding the core, wherein the core and the sheath comprise different polymers. For example, the core comprises a first polymer, and the sheath comprises a second polymer, wherein the first polymer and the second polymer are different (e.g., the first polymer and the second polymer have different melting temperature). Bicomponent fibers are typically used for producing nonwoven materials by air-laid techniques.

The presently disclosed subject matter contemplates the use of synthetic fibers, such as high core bicomponent fibers. Bicomponent fibers having a core and sheath are known in the art, but the present disclosure utilizes bicomponent fibers having a high core to sheath ratio that exceeds <NUM>:<NUM>, i.e., the high core bicomponent fibers comprise more than <NUM>% core by weight. Without being bound to a particular theory, it is believed that the high core bicomponent fibers can impart improved physical integrity, resiliency, and resistance to mechanical compression and/or tension to a nonwoven material. For example, the high core bicomponent fibers can impart these improved properties due to the increased volume of the core relative to the sheath.

As embodied herein, the high core bicomponent fibers can have a polyethylene sheath. The core of the high core bicomponent fibers can be made from a polymer with a melting point greater than about <NUM> and higher density than the polyethylene sheath. For example and not limitation, suitable core polymers include high melt point polyesters, such as poly(ethylene terephthalate) (PET), and polypropylene (PP). The core to sheath ratio of the high core bicomponent fibers can range from about <NUM>:<NUM> to about <NUM>:<NUM>, or from about <NUM>:<NUM> to about <NUM>:<NUM>, or from about <NUM>:<NUM> to about <NUM>:<NUM>.

In certain embodiments, a high core bicomponent fiber can have a PET core and a polyethylene sheath in an eccentric configuration, wherein the PET core forms more than about <NUM>% and no more than about <NUM>% by weight of the fiber. For example, and not limitation, the PET core can form from about <NUM>% to about <NUM>% by weight of the fiber, and preferably, about <NUM>% by weight of the fiber. In alternative embodiments, the high core bicomponent fibers can comprise a polypropylene core and a polyethylene sheath. In particular embodiments, such a high core bicomponent fiber can have a dtex of from about <NUM> dtex and a cut length of about <NUM>, although a person of skill in the art will appreciate that the bicomponent fiber can be formed with other thicknesses and cut lengths. For example and not limitation, the high core bicomponent fiber can have a dtex of from about <NUM> dtex to about <NUM> dtex, or from about <NUM> dtex to about <NUM> dtex. Additionally or alternatively, the high core bicomponent fiber can have a cut length of from about <NUM> to about <NUM>.

In addition to high core bicomponent fibers, the nonwoven material can further include any suitable additional bicomponent fibers, as known in the art, provided that it includes a low core bicomponent fiber as defined in claim <NUM>. The additional bicomponent fibers can be conventional, commercially available fibers. The low core bicomponent fibers have a core to sheath ratio of less than <NUM>:<NUM>, i.e., the low core bicomponent fibers comprise less than <NUM>% core by weight, as defined in claim <NUM>. For example, suitable low core bicomponent fibers can comprise a PET core and a polyethylene sheath in an eccentric configuration and the PET core can form at least about <NUM>% and less than about <NUM>% by weight of the fiber, preferable from about <NUM>% to about <NUM>% by weight of the fiber, and more preferably about <NUM>% by weight the fiber. In certain embodiments, a low core bicomponent fiber can impart improved strength to a nonwoven material, e.g., due to increased inter-fiber bonding due to the high volume of the sheath relative to the core. Low core bicomponent fibers can have a core to sheath ratio of <NUM>:<NUM>, i.e., the low core bicomponent fibers comprise <NUM>% core by weight.

However, many other varieties of bicomponent fibers are used in the manufacture of nonwoven materials, particularly those produced for use in airlaid techniques, and are suitable for use in the presently disclosed nonwoven materials. Various bicomponent fibers suitable for use in the presently disclosed subject matter are disclosed in <CIT> and <CIT>. Examples of bicomponent fiber manufacturers include, but are not limited to, Trevira (Bobingen, Germany), Fiber Innovation Technologies (Johnson City, TN) and ES Fiber Visions (Athens, GA).

The additional bicomponent fibers can also incorporate a variety of polymers as their core and sheath components. Bicomponent fibers that have a PE (polyethylene) or modified PE sheath typically have a PET (polyethylene terephthalate) or PP (polypropylene) core. In one embodiment, the bicomponent fibers have a core made of polypropylene and a sheath made of polyethylene. Alternatively, or additionally, the bicomponent fibers can have a core made of polyester (e.g., PET) and a sheath made of polyethylene.

As embodied herein, the bicomponent fiber can be low staple fibers having a dtex from about <NUM> dtex to about <NUM> dtex, or from about <NUM> dtex to about <NUM> dtex, and more preferably no more than about <NUM> dtex. For example, the dtex of the bicomponent fiber can be about <NUM> dtex, about <NUM> dtex, about <NUM> dtex, about <NUM> dtex, about <NUM> dtex, about <NUM> dtex, or about <NUM> dtex. The length of the bicomponent fiber can be from about <NUM> to about <NUM>, preferably from about <NUM> to about <NUM>, more preferably from about <NUM> to about <NUM>, even more preferably from about <NUM> to about <NUM>. In particular embodiments, the length of the bicomponent fiber is from about <NUM> to about <NUM>, or about <NUM>, or about <NUM>.

Bicomponent fibers are typically fabricated commercially by melt spinning. In this procedure, each molten polymer is extruded through a die, for example, a spinneret, with subsequent pulling of the molten polymer to move it away from the face of the spinneret. This is followed by solidification of the polymer by heat transfer to a surrounding fluid medium, for example chilled air, and taking up of the now solid filament. Non-limiting examples of additional steps after melt spinning can also include hot or cold drawing, heat treating, crimping and cutting. This overall manufacturing process is generally carried out as a discontinuous two-step process that first involves spinning of the filaments and their collection into a tow that comprises numerous filaments. During the spinning step, when molten polymer is pulled away from the face of the spinneret, some drawing of the filament does occur which can also be called the draw-down. This is followed by a second step where the spun fibers are drawn or stretched to increase molecular alignment and crystallinity and to give enhanced strength and other physical properties to the individual filaments. Subsequent steps can include, but are not limited to, heat setting, crimping and cutting of the filament into fibers. The drawing or stretching step can involve drawing the core of the bicomponent fiber, the sheath of the bicomponent fiber or both the core and the sheath of the bicomponent fiber depending on the materials from which the core and sheath are comprised as well as the conditions employed during the drawing or stretching process.

Bicomponent fibers can also be formed in a continuous process where the spinning and drawing are done in a continuous process. During the fiber manufacturing process it is desirable to add various materials to the fiber after the melt spinning step at various subsequent steps in the process. These materials can be referred to as "finish" and be comprised of active agents such as, but not limited to, lubricants and anti-static agents. The finish is typically delivered via an aqueous based solution or emulsion. Finishes can provide desirable properties for both the manufacturing of the bicomponent fiber and for the user of the fiber, for example in an airlaid or wetlaid process.

Numerous other processes are involved before, during and after the spinning and drawing steps and are disclosed in <CIT>,<CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT>,<CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT>,<CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT> <CIT>, <CIT>, <CIT>, <CIT>,<CIT>, and <CIT>.

The presently disclosed subject matter can also include, but are not limited to, articles that contain bicomponent fibers that are partially drawn with varying degrees of draw or stretch, highly drawn bicomponent fibers and mixtures thereof. These can include, but are not limited to, a highly drawn polyester core bicomponent fiber with a variety of sheath materials, specifically including a polyethylene sheath such as Trevira-<NUM> (Varde, Denmark) or a highly drawn polypropylene core bicomponent fiber with a variety of sheath materials, specifically including a polyethylene sheath such as ES FiberVisions AL-Adhesion-C (Varde, Denmark). Additionally, Trevira T265 bicomponent fiber (Varde, Denmark), having a partially drawn core with a core made of polybutylene terephthalate (PBT) and a sheath made of polyethylene can be used. The use of both partially drawn and highly drawn bicomponent fibers in the same structure can be leveraged to meet specific physical and performance properties based on how they are incorporated into the structure.

The bicomponent fibers of the presently disclosed subject matter are not limited in scope to any specific polymers for either the core or the sheath as any partially drawn core bicomponent fiber can provide enhanced performance regarding elongation and strength. The degree to which the partially drawn bicomponent fibers are drawn is not limited in scope as different degrees of drawing will yield different enhancements in performance. The scope of the partially drawn bicomponent fibers encompasses fibers with various core sheath configurations including, but not limited to concentric, eccentric, side by side, islands in a sea, pie segments and other variations. The relative weight percentages of the core and sheath components of the total fiber can be varied. In addition, the scope of this subject matter covers the use of partially drawn homopolymers such as polyester, polypropylene, nylon, and other melt spinnable polymers. The scope of this subject matter also covers multicomponent fibers that can have more than two polymers as part of the fiber structure.

Any cellulose fibers known in the art, including cellulose fibers of any natural origin, such as those derived from wood pulp or regenerated cellulose, can be used in a cellulose fiber layer. In certain embodiments, cellulose fibers include, but are not limited to, digested fibers, such as kraft, prehydrolyzed kraft, soda, sulfite, chemi-thermal mechanical, and thermomechanical treated fibers, derived from softwood, hardwood or cotton linters. In other embodiments, cellulose fibers include, but are not limited to, kraft digested fibers, including prehydrolyzed kraft digested fibers. In certain embodiments, the cellulosic fibers include bonded natural cellulosic fibers.

Non-limiting examples of cellulose fibers suitable for use in this subject matter are the cellulose fibers derived from softwoods, such as pines, firs, and spruces. Other suitable cellulose fibers include, but are not limited to, those derived from Esparto grass, bagasse, kemp, flax, hemp, kenaf, and other lignaceous and cellulosic fiber sources. Suitable cellulose fibers include, but are not limited to, bleached Kraft southern pine fibers sold under the trademark FOLEY FLUFFS® (available from GP Cellulose).

The nonwoven material of the disclosed subject matter can also include, but is not limited to, a commercially available bright fluff pulp including, but not limited to, southern softwood kraft (such as Golden Isles® <NUM> from GP Cellulose) or southern softwood fluff pulp (such as Treated FOLEY FLUFFS® or Golden Isles® <NUM> from GP Cellulose), northern softwood sulfite pulp (such as T <NUM> from Weyerhaeuser), or hardwood pulp (such as eucalyptus). While certain pulps may be preferred based on a variety of factors, any cellulosic fluff pulp or mixtures thereof can be used. In certain embodiments, wood cellulose, cotton linter pulp, chemically modified cellulose such as crosslinked cellulose fibers and highly purified cellulose fibers can be used. Non-limiting examples of additional pulps are FOLEY FLUFFS® FFTAS (also known as FFTAS or GP Cellulose FFT-AS pulp), and Weyco CF401.

In certain embodiments, fine fibers, such as certain softwood fibers can be used. Certain non-limiting examples of such fine fibers, with pulp fiber coarseness properties are provided in Table <NUM> with reference to <NPL>.

In certain embodiments, fine fibers, such as certain hardwood fibers can be used. Certain non-limiting examples of such fine fibers, with pulp fiber coarseness properties are provided in Table <NUM> with reference, at least in part, to Horn, R. , Morphology of Pulp Fiber from Hardwoods and Influence on Paper Strength, Research Paper FPL <NUM>, Forest Products Laboratory, U. Department of Agriculture (<NUM>) and Bleached Eucalyptus Kraft Pulp ECF Technical Sheet (April <NUM>) (available at: https://www. metsafibre. com/en/Documents/Data-sheets/Cenibra-euca-Eucalyptus.

In certain embodiments, the cellulosic fibers can have a Kajaani weighted average length of about <NUM> or less, about <NUM> or less, about <NUM> or less, about <NUM> or less, about <NUM> or less, or about <NUM> or less. In certain embodiments, the cellulosic fibers can have a Kajaani weighted average length of between about <NUM> and about <NUM>, about <NUM> and about <NUM>, or about <NUM> and about <NUM>. In particular embodiments, the cellulosic fibers can have a Kajaani weighted average length of about <NUM>, about <NUM>, about <NUM>, about <NUM>, about <NUM>, about <NUM>, about <NUM>, or about <NUM>.

In certain embodiments, the cellulosic fibers can have a coarseness finer than about <NUM>/<NUM>, about <NUM>/<NUM>, about <NUM>/<NUM>, or about <NUM>/<NUM>. In certain embodiments, the cellulosic fibers can have a coarseness of between about <NUM>/<NUM> and about <NUM>/<NUM>, about <NUM>/<NUM> and about <NUM>/<NUM>, about <NUM>/<NUM> and about <NUM>/<NUM>, or about <NUM>/<NUM> and about <NUM>/<NUM>. In particular embodiments, the cellulosic fibers can have a coarseness of about <NUM>/<NUM>, about <NUM>/<NUM>, about <NUM>/<NUM>, about <NUM>/<NUM>, about <NUM>/<NUM>, about <NUM>/<NUM>, about <NUM>/<NUM>, about <NUM>/<NUM>, or about <NUM>/<NUM>.

In certain embodiments, the cellulosic fibers can have a Kajaani weighted average length of about <NUM> or less and a coarseness finer than about <NUM>/<NUM>. In certain embodiments, the cellulosic fibers can have a Kajaani weighted average length of about <NUM> or less and a coarseness finer than about <NUM>/<NUM>. In particular embodiments, the cellulosic fibers can comprise bonded hardwood natural cellulosic fibers having a Kajaani weighted average length of about <NUM> or less and a coarseness finer than about <NUM>/<NUM>. In particular embodiments, the cellulosic fibers can comprise bonded hardwood natural cellulosic fibers having a Kajaani weighted average length of about <NUM> or less and a coarseness finer than about <NUM>/<NUM>. Structures having fibers, e.g., hardwood fibers, with these parameters allow for high capillary action with slow migration of liquid through the structure.

In certain non-limiting embodiments, the nonwoven materials described herein can include binders. Suitable binders include, but are not limited to, liquid binders and powder binders. Non-limiting examples of liquid binders include emulsions, solutions, or suspensions of binders. Non-limiting examples of binders include polyethylene powders, copolymer binders, vinylacetate ethylene binders, styrene-butadiene binders, urethanes, urethane-based binders, acrylic binders, thermoplastic binders, natural polymer-based binders, and mixtures thereof.

Suitable binders include, but are not limited to, copolymers, including vinyl-chloride containing copolymers such as Wacker Vinnol <NUM>, Vinnol <NUM>, and Vinnol <NUM>, vinylacetate ethylene ("VAE") copolymers, which can have a stabilizer such as Wacker Vinnapas <NUM>, Wacker Vinnapas EF <NUM>, Wacker Vinnapas EP907, Wacker Vinnapas EP129, Celanese Duroset E130, Celanese Dur-O-Set Elite <NUM><NUM>-<NUM> and Celanese Dur-O-Set TX-<NUM>, Celanese <NUM>-524A, polyvinyl alcohol-polyvinyl acetate blends such as Wacker Vinac <NUM>, vinyl acetate homopolyers, polyvinyl amines such as BASF Luredur, acrylics, cationic acrylamides, polyacryliamides such as Bercon Berstrength <NUM> and Bercon Berstrength <NUM>, hydroxyethyl cellulose, starch such as National Starch CATO RTM <NUM>, National Starch CATO RTM <NUM>, National Starch Optibond, National Starch Optipro, or National Starch OptiPLUS, guar gum, styrene-butadienes, urethanes, urethane-based binders, thermoplastic binders, acrylic binders, and carboxymethyl cellulose such as Hercules Aqualon CMC. In certain embodiments, the binder is a natural polymer-based binder. Non-limiting examples of natural polymer-based binders include polymers derived from starch, cellulose, chitin, and other polysaccharides.

In certain embodiments, the binder is water-soluble. In one embodiment, the binder is a vinylacetate ethylene copolymer. One non-limiting example of such copolymers is EP907 (Wacker Chemicals, Munich, Germany). Vinnapas EP907 can be applied at a level of about <NUM>% solids incorporating about <NUM>% by weight Aerosol OT (Cytec Industries, West Paterson, N. ), which is an anionic surfactant. Other classes of liquid binders such as styrene-butadiene and acrylic binders can also be used.

In certain embodiments, the binder is not water-soluble. Examples of these binders include, but are not limited to, Vinnapas <NUM> and <NUM> (Wacker), which can have an opacifier and whitener, including, but not limited to, titanium dioxide, dispersed in the emulsion. Other binders include, but are not limited to, Celanese Emulsions (Bridgewater, N. ) Elite <NUM> and Elite <NUM>.

In certain embodiments, the binder is a thermoplastic binder. Such thermoplastic binders include, but are not limited to, any thermoplastic polymer which can be melted at temperatures which will not extensively damage the cellulose fibers. Preferably, the melting point of the thermoplastic binding material will be less than about <NUM>. Examples of suitable thermoplastic materials include, but are not limited to, suspensions of thermoplastic binders and thermoplastic powders. In particular embodiments, the thermoplastic binding material can be, for example, polyethylene, polypropylene, polyvinylchloride, and/or polyvinylidene chloride.

The binder can be non-crosslinkable or crosslinkable. In certain embodiments, the binder is WD4047 urethane-based binder solution supplied by HB Fuller. In one embodiment, the binder is Michem Prime <NUM>-45N dispersion of ethylene acrylic acid ("EAA") copolymer supplied by Michelman. In certain embodiments, the binder is Dur-O-Set Elite 22LV emulsion of VAE binder supplied by Celanese Emulsions (Bridgewater, N. As noted above, in particular embodiments, the binder is crosslinkable. It is also understood that crosslinkable binders are also known as permanent wet strength binders. A permanent wet-strength binder includes, but is not limited to, Kymene® (Hercules Inc. , Wilmington, Del. ), Parez® (American Cyanamid Company, Wayne, N. ), Wacker Vinnapas or AF192 (Wacker Chemie AG, Munich, Germany), or the like. Various permanent wet-strength agents are described in <CIT>, <CIT>, and <CIT>. Other permanent wet-strength binders include, but are not limited to, polyamine-epichlorohydrin, polyamide epichlorohydrin or polyamide-amine epichlorohydrin resins, which are collectively termed "PAE resins". Non-limiting exemplary permanent wet-strength binders include Kymene <NUM> or Kymene 557LX (Hercules Inc. , Wilmington, Del. ) and have been described in <CIT> and <CIT>.

Alternatively, in certain embodiments, the binder is a temporary wet-strength binder. The temporary wet-strength binders include, but are not limited to, Hercobond® (Hercules Inc. , Wilmington, Del. ), Parez® <NUM> (American Cyanamid Company, Wayne, N. ), Parez® <NUM> (American Cyanamid Company, Wayne, N. ), or the like. Other suitable temporary wet-strength binders include, but are not limited to, dialdehyde starch, polyethylene imine, mannogalactan gum, glyoxal, and dialdehyde mannogalactan. Other suitable temporary wet-strength agents are described in <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, and <CIT>.

In certain embodiments, binders are applied as emulsions in amounts ranging from about <NUM> gsm to about <NUM> gsm, or from about <NUM> gsm to about <NUM> gsm, or from about <NUM> gsm to about <NUM> gsm. The emulsion can further include one or more additional components. For example and not limitation, the emulsion can include one or more surfactants in an amount of from about <NUM> wt-% to about <NUM> wt-% or from about <NUM> wt-% to about <NUM> wt-% based on the total weight of the emulsion. In certain non-limiting embodiments, the emulsion can include one or more surfactants in an amount of about <NUM> wt-% based on the total weight of the emulsion. The binder, whether or not part of the emulsion, can be applied to one side of a fibrous layer, preferably an externally facing layer. Alternatively, binder can be applied to both sides of a layer, in equal or disproportionate amounts.

The materials of the presently disclosed subject matter can also contain other additives. For example, the materials can contain superabsorbent polymer (SAP). The types of superabsorbent polymers which may be used in the disclosed subject matter include, but are not limited to, SAPs in their particulate form such as powder, irregular granules, spherical particles, staple fibers and other elongated particles. <CIT>; <CIT>; <CIT>; <CIT>; <CIT>; and <CIT>, describe various superabsorbent polymers and methods of making superabsorbent polymers. One example of a superabsorbent polymer forming system is crosslinked acrylic copolymers of metal salts of acrylic acid and acrylamide or other monomers such as <NUM>-acrylamido-<NUM>-methylpropanesulfonic acid. Many conventional granular superabsorbent polymers are based on poly(acrylic acid) which has been crosslinked during polymerization with any of a number of multi-functional co-monomer crosslinking agents well-known in the art. Examples of multi-functional crosslinking agents are set forth in <CIT>; <CIT>; <CIT>; and <CIT>. For instance, crosslinked carboxylated polyelectrolytes can be used to form superabsorbent polymers. Other water-soluble polyelectrolyte polymers are known to be useful for the preparation of superabsorbents by crosslinking, these polymers include: carboxymethyl starch, carboxymethyl cellulose, chitosan salts, gelatine salts, etc. They are not, however, commonly used on a commercial scale to enhance absorbency of dispensable absorbent articles mainly due to their higher cost. Superabsorbent polymer granules useful in the practice of this subject matter are commercially available from a number of manufacturers, such as BASF, Dow Chemical (Midland, Mich. ), Stockhausen (Greensboro, N. ), Chemdal (Arlington Heights, Ill. ), and Evonik (Essen, Germany). Non-limiting examples of SAP include a surface crosslinked acrylic acid-based powder such as Stockhausen <NUM> or SX70, BASF HySorb FEM 33N, or Evonik Favor SXM <NUM>.

In certain embodiments, SAP can be used in a layer in amounts ranging from about <NUM> wt-% to about <NUM> wt-% based on the total weight of the structure. In particular embodiments, a layer comprising <NUM> wt-% SAP can be disposed between two adjacent layers containing fibers. In certain embodiments, the amount of SAP in a layer can range from about <NUM> gsm to about <NUM> gsm, or from about <NUM> gsm to about <NUM> gsm, or from about <NUM> gsm to about <NUM> gsm. In particular embodiments, the amount of SAP in an layer can be about <NUM> gsm, about <NUM> gsm, about <NUM> gsm, about <NUM> gsm, about <NUM> gsm, or about <NUM> gsm.

The presently disclosed subject matter provides for a nonwoven material that incorporates cellulosic fibers and synthetic fibers, as defined in claim <NUM>. As embodied herein, the nonwoven material includes at least three layers. In certain non-limiting embodiments, the nonwoven material includes more than three layers.

As embodied herein, the nonwoven material is an airlaid material. For example, and not by limitation, the material can be a thermally bonded airlaid (TBAL) material comprising cellulose fibers. In certain non-limiting embodiments, the material can be a multi-bonded airlaid (MBAL) material comprising cellulose fibers. The material can further include a binder.

The nonwoven material includes at least three layers. In certain non-limiting embodiments, the at least three layers can be provided adjacent to each other. The at least three layers can each have identical or different compositions from each other. In certain non-limiting embodiments, each of the layers can include cellulose fibers and bicomponent synthetic fibers. For example and not by limitation, one or more layers can include cellulose fibers in an amount from about <NUM> wt-% to about <NUM> wt-%. In certain non-limiting embodiments, one or more layers can include about <NUM> wt-% to about <NUM> wt-%, about <NUM> wt-% to about <NUM> wt-%, about <NUM> wt-% to about <NUM> wt-%, about <NUM> wt-% to about <NUM> wt-% cellulose fibers. In certain non-limiting embodiments, one or more layers can include about <NUM> wt-%, about <NUM> wt-%, about <NUM> wt-%, about <NUM> wt-%, about <NUM> wt-%, or about <NUM> wt-% cellulose fibers. The cellulose fibers can comprise eucalyptus pulp. For example and not by limitation, one or more layers can include synthetic fibers in an amount from about <NUM> wt-% to about <NUM> wt-%. In certain non-limiting embodiments, one or more layers can include about <NUM> wt-% to about <NUM> wt-% or about <NUM> wt-% to about <NUM> wt-% synthetic fibers. In certain non-limiting embodiments, one or more layers can include about <NUM> wt-%, about <NUM> wt-%, about <NUM> wt-%, about <NUM> wt-%, or about <NUM> wt-% synthetic fibers. The synthetic fibers can comprise bicomponent binder fibers, eccentric bicomponent binder fibers, or a combination thereof. In certain non-limiting embodiments, one or more layers can include about <NUM> wt-% to about <NUM> wt-% synthetic fibers and about <NUM> wt-% to about <NUM> wt-% cellulose fibers. In certain non-limiting embodiments, one or more layers can include about <NUM> wt-% to about <NUM> wt-% weight percent synthetic fibers and about <NUM> wt-% to about <NUM> wt-% cellulose fibers. In certain non-limiting embodiments, one or more layers can include about <NUM> wt-% cellulose fibers and about <NUM> wt-% synthetic fibers.

In certain non-limiting embodiments, the nonwoven material can include at least three layers having at least two layers including cellulose fibers and bicomponent synthetic fibers and at least one layer including synthetic fibers. For example, the at least one layer including synthetic fibers can include about <NUM> wt-% synthetic fibers. In certain non-limiting embodiments, the nonwoven material having at least three layers can include two layers including cellulose fibers and synthetic fibers and a layer including synthetic fibers. For example, the nonwoven material having at least three layers can include two layers including cellulose fibers and synthetic fibers and one layer including only synthetic fibers. Additionally, the at least two layers comprising cellulose fibers can comprise eucalyptus pulp. The at least three layers comprising synthetic fibers can comprise bicomponent binder fibers, eccentric bicomponent binder fibers, or a combination thereof. In certain non-limiting embodiments, the at least two layers can each comprise about <NUM> wt-% to about <NUM> wt-% synthetic fibers and about <NUM> wt-% to about <NUM> wt-% cellulose fibers. In certain non-limiting embodiments, the at least two layers can comprise about <NUM> wt-% to about <NUM> wt-% synthetic fibers and about <NUM> wt-% to about <NUM> wt-% cellulose fibers. In certain non-limiting embodiments, the at least two layers can comprise about <NUM> wt-% cellulose fibers and about <NUM> wt-% synthetic fibers. Additionally, a binder can be applied to a surface of the structure, for example, a bottom surface of the structure. In certain non-limiting embodiments, the three-layer nonwoven can further include super absorbent polymer (SAP), for example, to increase liquid capacity and slow the release of absorbed liquid. In certain non-limiting embodiments, a tacky adhesive can be provided on at least a portion of the structure. For example, about <NUM> gsm to about <NUM> gsm of a tacky adhesive can be added to the structure. In certain non-limiting embodiments, the structure can include a tacky adhesive in an about from about <NUM> gsm to about <NUM> gsm, about <NUM> gsm, to about <NUM> gsm, about <NUM> gsm to about <NUM> gsm, about <NUM> gsm to about <NUM> gsm, about <NUM> gsm to about <NUM> gsm, about <NUM> gsm to about <NUM> gsm, about <NUM> gsm to about <NUM> gsm, about <NUM> gsm to about <NUM> gsm, about <NUM> gsm to about <NUM> gsm, about <NUM> gsm to about <NUM> gsm, about <NUM> gsm to about <NUM> gsm, about <NUM> gsm to about <NUM> gsm, about <NUM> gsm to about <NUM> gsm, about <NUM> gsm to about <NUM> gsm, about <NUM> gsm to about <NUM> gsm, about <NUM> gsm to about <NUM> gsm, about <NUM> gsm to about <NUM> gsm, about <NUM> gsm to about <NUM> gsm, about <NUM> gsm to about <NUM> gsm, or about <NUM> gsm to about <NUM> gsm. In certain non-limiting embodiments, the structure can include a tacky adhesive in an amount of about <NUM> gsm, about <NUM> gsm, about <NUM> gsm, about <NUM> gsm, about <NUM> gsm, or about <NUM> gsm.

Additionally or alternatively, the structure can be coated on at least of a portion of its outer surface with a binder. The binder does not need to chemically bond with a portion of the layer, although it is preferred that the binder remain associated in close proximity with the layer, by coating, adhering, precipitation, or any other mechanism such that it is not dislodged from the layer during normal handling of the layer. For convenience, the association between the layer and the binder discussed above can be referred to as the bond, and the compound can be said to be bonded to the layer. If present, the binder can be applied in amounts ranging from about <NUM> gsm to about <NUM> gsm, or from about <NUM> gsm to about <NUM> gsm, or from about <NUM> gsm to about <NUM> gsm, or from about <NUM> gsm to about <NUM> gsm.

Overall, the first layer can have a basis weight of from about <NUM> gsm to about <NUM> gsm, or from about <NUM> gsm to about <NUM> gsm, or from about <NUM> gsm to about <NUM> gsm, or from about <NUM> gsm to about <NUM> gsm. When the first layer includes a blend of cellulosic fibers and synthetic fibers, the cellulosic fibers can be present in an amount of from about <NUM> wt-% to about <NUM> wt-% synthetic fibers and about <NUM> to about <NUM> wt-% cellulose fibers, or from about <NUM> wt-% to about <NUM> wt-% synthetic fibers and from about <NUM> wt-% to about <NUM> wt-% cellulose fibers, or from about <NUM> wt-% cellulose fibers and about <NUM> wt-% synthetic fibers. Alternatively, the first layer can include synthetic fibers. For example, the first layer can include about <NUM> wt-% synthetic fibers.

In these embodiments, the second layer, comprising cellulose fibers and synthetic fibers, can have a basis weight of from about <NUM> gsm to about <NUM> gsm, from about <NUM> gsm to about <NUM> gsm, from about <NUM> gsm, to about <NUM> gsm, or from about <NUM> gsm to about <NUM> gsm. When the second layer includes a blend of cellulosic fibers and synthetic fibers, the cellulosic fibers can be present in an amount of from about <NUM> wt-% to about <NUM> wt-% synthetic fibers and about <NUM> wt-% to about <NUM> wt-% cellulose fibers, or from about <NUM> wt-% to about <NUM> wt-% synthetic fibers and from about <NUM> wt-% to about <NUM> wt-% cellulose fibers, or from about <NUM> wt-% cellulose fibers and about <NUM> wt-% synthetic fibers.

The material can optionally include a further layer, disposed between the first layer and the second layer, comprising cellulose fibers and synthetic fibers, which can have a basis weight of from about <NUM> gsm to about <NUM> gsm, or from about <NUM> gsm to about <NUM> gsm, or from about <NUM> gsm to about <NUM> gsm, or from about <NUM> gsm to about <NUM> gsm. When the further layer includes a blend of cellulosic fibers and synthetic fibers, the cellulosic fibers can be present in an amount of from about <NUM> wt-% to about <NUM> wt-% synthetic fibers and about <NUM> wt-% to about <NUM> wt-% cellulose fibers, or from about <NUM> wt-% to about <NUM> wt-% synthetic fibers and from about <NUM> wt-% to about <NUM> wt-% cellulose fibers, or from about <NUM> wt-% cellulose fibers and about <NUM> wt-% synthetic fibers.

The materials are prepared by airlaid processes. Airlaid processes include, but are not limited to, the use of one or more forming heads to deposit raw materials of differing compositions in selected order in the manufacturing process to produce a product with distinct strata. This allows great versatility in the variety of products which can be produced.

In one embodiment, the material is prepared as a continuous airlaid web. The airlaid web is typically prepared by disintegrating or defiberizing a cellulose pulp sheet or sheets, typically by hammermill, to provide individualized fibers. Rather than a pulp sheet of virgin fiber, the hammermills or other disintegrators can be fed with recycled airlaid edge trimmings and off-specification transitional material produced during grade changes and other airlaid production waste. Being able to thereby recycle production waste would contribute to improved economics for the overall process. The individualized fibers from whichever source, virgin or recycled, are then air conveyed to forming heads on the airlaid web-forming machine. A number of manufacturers make airlaid web forming machines suitable for use in the disclosed subject matter, including Dan-Web Forming of Aarhus, Denmark, M&J Fibretech A/S of Horsens, Denmark, Rando Machine Corporation, Macedon, N. which is described in <CIT>, Margasa Textile Machinery of Cerdanyola del Valles, Spain, and DOA International of Wels, Austria. While these many forming machines differ in how the fiber is opened and air-conveyed to the forming wire, they all are capable of producing the webs of the presently disclosed subject matter. The Dan-Web forming heads include rotating or agitated perforated drums, which serve to maintain fiber separation until the fibers are pulled by vacuum onto a foraminous forming conveyor or forming wire. In the M&J machine, the forming head is basically a rotary agitator above a screen. The rotary agitator may comprise a series or cluster of rotating propellers or fan blades. Other fibers, such as a synthetic thermoplastic fiber, are opened, weighed, and mixed in a fiber dosing system such as a textile feeder supplied by Laroche S. of Cours-La Ville, France. From the textile feeder, the fibers are air conveyed to the forming heads of the airlaid machine where they are further mixed with the comminuted cellulose pulp fibers from the hammer mills and deposited on the continuously moving forming wire. Where defined layers are desired, separate forming heads may be used for each type of fiber. Alternatively or additionally, one or more layers can be prefabricated prior to being combined with additional layers, if any. In certain embodiments, the forming wire can be patterned, such that at least one layer of the resulting nonwoven material is patterned.

The airlaid web is transferred from the forming wire to a calendar or other densification stage to densify the web, if necessary, to increase its strength and control web thickness. In one embodiment, the fibers of the web are then bonded by passage through an oven set to a temperature high enough to fuse the included thermoplastic or other binder materials. In a further embodiment, secondary binding from the drying or curing of a latex spray or foam application occurs in the same oven. The oven can be a conventional through-air oven, be operated as a convection oven, or may achieve the necessary heating by infrared or even microwave irradiation. In particular embodiments, the airlaid web can be treated with additional additives before or after heat curing. The airlaid web can optionally be embossed or otherwise patterned. Subsequently, the airlaid web can be rolled into bale on a roller.

The nonwoven materials of the disclosed subject matter can be used for any application as known in the art. The nonwoven materials can be used alone or as a component in other consumer products. For example, the nonwoven materials can be used either alone or as a component in a variety of absorbent articles including cleaning articles, personal care wipes, baby diapers, adult incontinence products, sanitary napkins and the like. Absorbent cleaning products include wipes, sheets, towels, and the like. The absorbency of the nonwoven materials can aid in dirt and mess removal in such cleaning applications. In certain aspects, the layered structure of the disclosed nonwoven material can provide a dual-sided substrate suitable for use as wipes, sheets, towels, and the like.

The use of cellulosic fibers having a Kajaani weighted average length shorter than about <NUM> and a coarseness finer than about <NUM>/<NUM> and therefore having high capillary action allows for slow migration of liquid through the structure. In a dry state, the layer including cellulosic fibers having the parameters described above distributes the liquid throughout the structure and prevents rapid release of the liquid due to high capillary action. Therefore, the nonwoven materials described herein can be used as highly absorbent materials for cleaning liquids.

In certain aspects, the present disclosure relates to nonwoven materials having increased performance as a cleaning apparatus. The nonwoven materials described herein can also be used in pre-moistened cleaning materials. Since the nonwoven materials described herein have high capillary action allowing for a metered release of absorbed liquids, a single pre-moistened wipe including these nonwoven materials can be used to clean a larger surface area.

Additionally, the material can be designed such that an outer layer that contacts the surface to be cleaned can comprise bonded synthetic fibers. The bonded synthetic fibers can provide increased article pick-up and allow an outer surface to provide a scrubbing surface.

In certain non-limiting embodiments, the nonwoven is a multi-layer unitary absorbent material whose individual layers have specific characteristics and is a medium by which typical cleaning formulations used for cleaning hard surfaces (e.g., liquid or lotions) can be metered onto or absorbed from a surface to be cleaned.

In certain non-limiting embodiments, the layer adjacent to a floor side comprises eucalyptus fibers that aid to release and distribute the liquid, while other layers serve as to store a liquid. In certain non-limiting embodiments, the intermediate layer disposed between a first and a second outer layer comprises eucalyptus fibers and provides a metered release of the liquid.

As noted above, in certain non-limiting embodiments, the nonwoven materials of the present disclosure can be used in conjunction of a variety of cleaning formulations (e.g., liquids or lotions) known in the art. Such cleaning formulations can be in the form of a solution or emulsion. In certain embodiments, the cleaning formulation is aqueous based. In a particular non-limiting embodiment, the cleaning formulation is non-aqueous based.

The following examples are merely illustrative of the presently disclosed subject matter and they should not be considered as limiting the scope of the disclosed subject matter in any way.

The present Example provides multi-layer nonwoven substrates that can retain liquid and provide a metered release of liquid. Different compositions were prepared and tested as follows. In this Example, nonwoven substrates having multiple layers were formed and tested for liquid retention. A Control Sample and Samples <NUM> to <NUM> were cut into samples measuring 10in. being the machine direction, <NUM> inc = <NUM>). The samples were placed in the center of a <NUM> gsm spunlace (wing) (10in. dimensions). A <NUM> gsm spunlace (cover stock) (10in. dimensions) was placed over the substrate. The layers of the samples were embossed together using an embossing plate and Carver press. The samples were then weighed.

The compositions of the Control Sample and Samples <NUM> to <NUM> are shown in Tables <NUM>-<NUM>, below.

The Control Sample was prepared and tested for comparative purposes. The Control Sample was constructed with three homogeneous layers each including cellulose and synthetic fibers. The substrate was a <NUM> gsm thermal-bonded Dan-Web Airlaid Nonwoven (TBAL) product with <NUM> wt-% bicomponent synthetic fibers. The Control Sample included three homogeneous layers. Each layer included <NUM> gsm of cellulose (GP <NUM>, semi-treated pulp made by Georgia-Pacific) blended with <NUM> gsm of synthetic fibers (Trevira Type <NUM> - <NUM> dtex <NUM>). The total weight of the structure was calculated to be <NUM> gsm.

Sample <NUM> was constructed with three homogeneous layers each including cellulose and synthetic fibers. The substrate is a <NUM> gsm thermal-bonded Dan-Web Airlaid Nonwoven (TBAL) product with <NUM> wt-% bicomponent synthetic fibers. Sample <NUM> included three layers. The bottom layer contained <NUM> percent of the overall structure. The bottom layer contained <NUM> gsm of cellulose (GP <NUM>, semi-treated pulp made by Georgia-Pacific) and <NUM> gsm synthetic fibers (Trevira Type <NUM> - <NUM> dtex <NUM>). The top and middle layers each contained <NUM> gsm of cellulose (GP <NUM>, semi-treated pulp made by Georgia-Pacific) and <NUM> gsm synthetic fibers (Trevira Type <NUM> - <NUM> dtex <NUM>). The total weight of the structure was calculated to be <NUM> gsm.

Sample <NUM> was constructed with three homogeneous layers each including cellulose and synthetic fibers. The substrate is a <NUM> gsm thermal-bonded Dan-Web Airlaid Nonwoven (TBAL) product with <NUM> wt-% bicomponent synthetic fibers. Sample <NUM> included three layers. The bottom layer contained <NUM> percent of the overall structure. The bottom layer contained <NUM> gsm of eucalyptus pulp (Suzano, untreated) and <NUM> gsm synthetic fibers (Trevira Type <NUM> - <NUM> dtex <NUM>). The top and middle layers each contained <NUM> gsm of cellulose (GP <NUM>, semi-treated pulp made by Georgia-Pacific) and <NUM> gsm synthetic fibers (Trevira Type <NUM> - <NUM> dtex <NUM>). The total weight of the structure was calculated to be <NUM> gsm.

Sample <NUM> was constructed with three homogeneous layers each including cellulose and synthetic fibers. The substrate is a <NUM> gsm thermal-bonded Dan-Web Airlaid Nonwoven (TBAL) product with <NUM> wt-% bicomponent synthetic fibers. Sample <NUM> included three layers. The top and bottom layers each contained <NUM> gsm of eucalyptus pulp (Suzano, untreated) and <NUM> gsm synthetic fibers (Trevira Type <NUM> - <NUM> dtex <NUM>). The middle layer contained <NUM> gsm of cellulose (GP <NUM>, semi-treated pulp made by Georgia-Pacific) and <NUM> gsm synthetic fibers (Trevira Type <NUM> - <NUM> dtex <NUM>). The total weight of the structure was calculated to be <NUM> gsm.

Samples <NUM> and <NUM> were prepared and tested for liquid retention. Samples <NUM> and <NUM> are unitary, absorbent composites composed of three layers, stacked one on another, and are designed to store liquid, provide a measured release of liquid, and replace spunlace that is used in commercially available disposable wet mopping cloths. Binder was applied to the bottom of the structures. The substrate was cut into about 10in. samples (10in. being the machine direction). Some of the 10in. samples were unembossed and were approximately <NUM> thick. Some of the 10in. samples were embossed with a pattern to a thickness of approximately <NUM>. The compositions of Samples <NUM> and <NUM> are shown in Tables <NUM> and <NUM>, respectively.

Sample <NUM> was constructed with three homogeneous layers with two layers including cellulose and synthetic fibers and one layer including synthetic fibers. The substrate is a <NUM> gsm multi-bonded Dan-Web Airlaid Nonwoven (MBAL) product with <NUM> percent bicomponent synthetic fibers and <NUM> percent binder. Sample <NUM> included three layers. The bottom layer contained <NUM> gsm of eucalyptus pulp (Suzano, untreated) and <NUM> gsm synthetic fibers (Trevira Type <NUM> - <NUM> dtex <NUM>). The middle layer contained <NUM> gsm of cellulose (GP <NUM>, fully-treated pulp made by Georgia-Pacific) and <NUM> gsm synthetic fibers (Trevira Type <NUM> - <NUM> dtex <NUM>). The top layer contained <NUM> gsm of eccentric bicomponent fibers (Trevira Type <NUM> - <NUM> dtex <NUM>). The binder, <NUM> gsm (Wacker Vinnapas <NUM>), was applied to the bottom (floor sweeping tool side) of the structure. The total weight of the structure was calculated to be <NUM> gsm.

Sample <NUM> was constructed with three homogeneous layers with two layers including cellulose and synthetic fibers and one layer including synthetic fibers. The substrate is a <NUM> gsm multi-bonded Dan-Web Airlaid Nonwoven (MBAL) product with <NUM> percent bicomponent synthetic fibers and <NUM> percent binder. Sample <NUM> included three layers. The bottom layer contained <NUM> gsm of cellulose (GP <NUM>, fully-treated pulp made by Georgia-Pacific) and <NUM> gsm synthetic fibers (Trevira Type <NUM> - <NUM> dtex <NUM>). The middle layer contained <NUM> gsm of eucalyptus pulp (Suzano, untreated) and <NUM> gsm synthetic fibers (Trevira Type <NUM> - <NUM> dtex <NUM>). The top layer contained <NUM> gsm of eccentric bicomponent fibers (Trevira Type <NUM> - <NUM> dtex <NUM>). The binder, <NUM> gsm (Wacker Vinnapas <NUM>), was applied to the bottom (floor sweeping tool side) of the structure. The total weight of the structure was calculated to be <NUM> gsm.

A study to quantitatively measure the release of a liquid or lotion from pre-moistened substrates was conducted to assess the amount of released from the wipes during cleaning.

Control Sample and Samples <NUM>-<NUM> were tested on an apparatus as shown in <FIG>. Sample <NUM> and Sample <NUM> were each tested embossed and unembossed. The apparatus included a flooring substrate fixture demonstrating an oak hardwood floor covering measuring approximately <NUM> (<NUM> ft) by <NUM> (<NUM> ft) and is surrounded by <NUM> (<NUM> in. ) tall wood baseboards in front of <NUM> (<NUM> in. ) walls on three sides of the perimeter. To measure release of liquid from each substrate, the substrate was cut in sample sizes and lotion in an amount of about <NUM> to about <NUM> times the substrate weight was added. The lotion had been extracted from pre-moistened wet mopping cloth wipes (Walmart® Great Value Wet Mopping Cloth wipes). The lotion was poured on the sample using a beaker, and a <NUM>-gram steel roll was rolled over the sample to distribute the lotion evenly throughout the sample. The sample was then loaded onto a floor sweeping tool. For the Control Sample and Samples <NUM>-<NUM>, the sweeping tool was then placed on the wet sample and a spunlace wing was wrapped around and secured into the holding ports on top of a manual sweeping tool head. The spunlace cover stock was touching the floor. The entire sweeping tool head and sample were weighed. For Sample <NUM> and Sample <NUM>, a manual sweeping tool head was placed on a wet sample and the sample was wrapped around the sweeping tool head and secured into the holding ports on top. The entire sweeping tool head and sample were weighed.

The sweeping tool head was loaded onto the testing apparatus which was designed to mop <NUM> ft<NUM> (<NUM> ft<NUM> = <NUM><NUM>) using even pressure and speed. The sweeping tool head was then lowered to the linoleum floor and start was pressed on the floor cleaning test. The floor was cleaned in a cleaning pattern illustrated in <FIG>. The cleaning head holder was modified in that a nominal <NUM> pounds of force was added to the flooring substrate and it operated at a nominal speed of <NUM> per second (<NUM> in. per second). The apparatus then cleaned <NUM> ft<NUM>. Once the testing apparatus had run the floor mop over <NUM> ft<NUM>, the floor was dried with a microfiber cloth, and the test was repeated by pressing home on the machine then start - without picking the mop up from the floor to reset to the start position. This procedure was repeated until <NUM> ft<NUM> - three cycles - had been completed. At the end of the third cycle, the floor sweeping tool was lifted from the floor, removed from the testing apparatus, and weighed without removing the sample from the tool. The tool and sample were then placed back on the machine and the same procedure as above was followed until <NUM> ft<NUM> - three additional testing cycles - were wiped. The floor sweeping tool was again lifted from the floor, removed from the testing apparatus, and weighed without removing the sample from the tool. The tool and sample were then placed back on the machine and the same procedure as above was followed until <NUM> ft<NUM> - four additional testing cycles - were wiped. The total number of testing cycles was ten.

The results are summarized in Table <NUM>. Samples <NUM> and <NUM> containing eucalyptus pulp retained more lotion than the Control Sample and Sample <NUM>. Particularly, Sample <NUM> containing eucalyptus fibers in the layer on the floor side of the structure retained <NUM> % more lotion (by weight) than Control Sample over <NUM>. In this case, the layers directly above the layer containing eucalyptus fibers provided a liquid storing area and the bottom layer aids to release and distribute lotion. The results also indicate that unembossed samples retained more lotion as compared to embossed samples.

Select samples were further tested and compared to commercially available products in a Tile Wetting Test. The Tile Wetting Test is designed to compare how much area can be swept with a pre-moistened material before it stops releasing liquid. The present Example tested the number of 12in. floor tiles a pre-moistened material can wet until an end point is reached in which no further liquid is released.

The testing area had dimensions about <NUM> feet long and about <NUM> feet wide and included waxed vinyl tiles. Prior to testing, the testing area was dry swept, mopped with clean water and dried.

The sample was weighed and placed on a head of a sweeping tool. The sweeping tool was then placed on the floor at one end of the testing area and pushed to the other end. The sweeping tool was then pushed back on a dry section of the testing area adjacent to the area previously swept. The pattern was repeated and the floor was observed and marked when the sample was no longer releasing any liquid. Once the sample was no longer releasing liquid, the number of 12in. tiles that had been mopped was recorded. After the sample had released all the liquid, the sample was reweighed to determine the amount of liquid loss. Each test was replicated <NUM> times.

Three compositions were tested: Control Sample, Sample <NUM> and Sample <NUM>. Compositions of these Samples are provided in Tables <NUM>, <NUM> and <NUM>, respectively. Commercially available Swiffer® Sweeper Wet - Wet Mopping Cloths with Gain® and Walmart® Great Value Wet Mopping Cloths were also tested. The results are summarized in Table <NUM>.

Results of the Tile Wetting Test provided that on average all three samples were able to wet more 12in. tiles than commercially available products. The Control Sample wetted on average <NUM> and <NUM> more tiles than commercially available products tested. Sample <NUM> wetted on average <NUM> and <NUM> more tiles than commercially available products tested. Sample <NUM> wetted on average <NUM> and <NUM> more tiles than commercially available products tested. These results provide for increased metered release of liquids in nonwoven materials having a layer on the floor sweeping side including eucalyptus fibers.

Select samples were further tested to evaluate cleaning and stain removal efficacy. Three compositions were tested: Control Sample, Sample <NUM> and Sample <NUM>. Compositions of these Samples are found in Tables <NUM>, <NUM>, and <NUM>, respectively. Commercially available Swiffer® Sweeper Wet - Wet Mopping Cloths with Gain® and Walmart® Great Value Wet Mopping Cloths were also tested. Using a Gardner Straight-Line Washability Apparatus (WA-<NUM>, Model D16VF) operating at <NUM> pound of pressure and <NUM> cycles per minute, a 4in. sample was cut and mounted on a scrubbing block. The apparatus was started and the number of cycles to remove each of five different stains from a vinyl tile (Armstrong Flooring <NUM> Feature Tile R627A) was recorded. A schematic of the testing apparatus is illustrated in <FIG>. To produce the stains, a vinyl tile was cut into a 4in. wide strip and five (<NUM>) <NUM>-inch ID O-rings were used to contain solutions while they dried on the vinyl tile. A solution (<NUM>) was added to the center of the O-ring every <NUM> hours until a total volume of <NUM> was added. Five different solutions were used, and stains therefrom tested, one solution per O-ring as described below. The solutions remained at room temperature for <NUM> hours until dry. The vinyl tile was then heated in an oven at <NUM> (<NUM> °F) for <NUM> hour. Samples were then tested within <NUM>-<NUM> hours.

The following stains were tested: hot chocolate, coffee, orange juice (high pulp), grape juice and potting soil. The hot chocolate (Swiss Miss®) was prepared according to instructions and powdered creamer was added (<NUM> tsp, Coffee Mate®). The coffee was prepared with instant coffee (Maxwell House®), water (<NUM>), sugar (<NUM> tsp), and powdered creamer (Coffee Mate®). The potting soil was prepared with a <NUM>:<NUM> blend of potting soil (Miracle Grow®) and water to produce mud. Prior to testing, the O-ring was removed and loose dirt was knocked off in order to simulate sweeping the floor leaving mud stain was on the vinyl tile prior to testing.

The results are summarized in Table <NUM>.

As illustrated in Table <NUM>, the two commercial samples provided similar results, with an exception of Walmart® Great Value Mopping Cloths showing slightly improved results on average at removing orange juice, grape juice and soil stains (<NUM> vs <NUM> cycles, <NUM> vs <NUM> cycles and <NUM> vs <NUM> cycles, respectively). The Control Sample provided improved results as compared to commercial products for all tested stains except for grape juice, where on average it showed the same results as Walmart® Great Value Wet Mopping Cloths. Sample <NUM> on average provided similar results in the removal of cocoa stains as the commercial samples and provided improved results on average at removing orange juice, grape juice and soil stains as compared to commercial samples and on average needed one more cycle to remove coffee stains than commercial samples. Sample <NUM> provided the improved results overall, on average less cycles were needed to clean any of the five stains as compared to commercially available samples and Control Sample and Sample <NUM>.

Sample <NUM> is a unitary, absorbent composite composed of a single layer which provides for the storage of liquid and a metered release of liquid.

The composition of Sample <NUM> is shown in Table <NUM>.

The substrate is a <NUM> gsm thermal-bonded Dan-Web Airlaid Nonwoven (TBAL) product with <NUM> wt-% bicomponent synthetic fibers. The sample includes a single homogeneous layer. The layer contains <NUM> gsm of eucalyptus pulp (Suzano, untreated) and <NUM> gsm synthetic fibers (Trevira Type <NUM> - <NUM> dtex <NUM>).

Sample <NUM> is a unitary, absorbent composite composed of two layers, stacked one on another, which provides for the storage of liquid and a metered release of liquid.

The substrate is a <NUM> gsm multi-bonded Dan-Web Airlaid Nonwoven (MBAL) product with <NUM> percent bicomponent synthetic fibers. The sample includes two layers. The bottom layer contains <NUM> gsm of eucalyptus pulp (Suzano, untreated) and <NUM> gsm synthetic fibers (Trevira Type <NUM> - <NUM> dtex <NUM>). The top layer contains <NUM> gsm of eccentric bicomponent fibers (Trevira Type <NUM> - <NUM> dtex <NUM>). The binder, <NUM> gsm (Wacker Vinnapas <NUM>), is applied to the bottom (floor sweeping tool side) of the structure.

Sample <NUM> is a unitary, absorbent composite composed of three layers, stacked one on another, which provides for the storage of liquid and a metered release of liquid.

The substrate is a <NUM> gsm multi-bonded Dan-Web Airlaid Nonwoven (MBAL) product with <NUM> percent bicomponent synthetic fibers and <NUM> percent binder. This sample includes three fiber layers. The bottom layer contains <NUM> gsm of eucalyptus pulp (Suzano, untreated) and <NUM> gsm synthetic fibers (Trevira Type <NUM> - <NUM> dtex <NUM>). The middle layer contains <NUM> gsm of cellulose (GP <NUM>, fully-treated pulp made by Georgia-Pacific) and <NUM> gsm synthetic fibers (Trevira Type <NUM> - <NUM> dtex <NUM>). The top layer contains <NUM> gsm of eccentric bicomponent fibers (Trevira Type <NUM> - <NUM> dtex <NUM>). The binder, <NUM> gsm (Wacker Vinnapas <NUM>), is applied to the bottom (floor sweeping tool side) of the structure.

The substrate is a <NUM> gsm multi-bonded Dan-Web Airlaid Nonwoven (MBAL) product with <NUM> percent bicomponent synthetic fibers and <NUM> percent binder. Sample <NUM> includes three layers analogous to Sample <NUM>. The bottom layer contains <NUM> gsm of cellulose (GP <NUM>, fully-treated pulp made by Georgia-Pacific) and <NUM> gsm synthetic fibers (Trevira Type <NUM> - <NUM> dtex <NUM>). The middle layer contains <NUM> gsm of eucalyptus pulp (Suzano, untreated) and <NUM> gsm synthetic fibers (Trevira Type <NUM> - <NUM> dtex <NUM>). The top layer contains <NUM> gsm of eccentric bicomponent fibers (Trevira Type <NUM> - <NUM> dtex <NUM>). The binder, <NUM> gsm (Wacker Vinnapas <NUM>), is applied to the bottom (floor sweeping tool side) of the structure.

After the sample is provided, <NUM>-<NUM> gsm of a tacky adhesive is added to the top layer (floor side), for example, to increase particle pick-up.

The present example provides unitary, absorbent composites composed of three layers, stacked one on another, which is designed to store liquid, offer a measured release of liquid, and replace the spunlace used in commercially available disposable wet mopping cloths.

The compositions of Sample 10A, Sample 10B, Sample 10C, and Sample 10D are shown in Tables <NUM>, <NUM>, <NUM>, and <NUM>, respectively.

Sample 10A included three layers. The bottom layer contained <NUM> gsm of cellulose (Golden Isles Leaf River <NUM>) and <NUM> gsm synthetic fibers (Trevira T255 <NUM><NUM>% core <NUM> dtex <NUM>). The middle layer contained <NUM> gsm of eucalyptus pulp (Suzano, untreated) and <NUM> gsm synthetic fibers (Trevira T255 <NUM><NUM>% core <NUM> dtex <NUM>). The top layer contained <NUM> gsm of eccentric bicomponent fibers (Trevira T-<NUM><NUM> dtex <NUM>). The binder, <NUM> gsm (Wacker Vinnapas <NUM>), was applied to the bottom (floor sweeping tool side) of the structure. The total weight of the structure was calculated to be <NUM> gsm.

Sample 10B included three layers. The bottom layer contained <NUM> gsm of cellulose (Golden Isles Leaf River <NUM>) and <NUM> gsm synthetic fibers (Trevira T255 <NUM><NUM>% core <NUM> dtex <NUM>). The middle layer contained <NUM> gsm of eucalyptus pulp (Suzano, untreated) and <NUM> gsm synthetic fibers (Trevira T255 <NUM><NUM>% core <NUM> dtex <NUM>). The top layer contained <NUM> gsm of eccentric bicomponent fibers (Trevira T-<NUM><NUM> dtex <NUM>). The binder, <NUM> gsm (Wacker Vinnapas <NUM>), was applied to the bottom (floor sweeping tool side) of the structure. The total weight of the structure was calculated to be <NUM> gsm.

Sample 10C included three layers. The bottom layer contained <NUM> gsm of cellulose (Golden Isles Leaf River <NUM>) and <NUM> gsm synthetic fibers (Trevira T255 <NUM> PEPET <NUM> dtex <NUM>). The middle layer contained <NUM> gsm of eucalyptus pulp (Suzano, untreated) and <NUM> gsm synthetic fibers (Trevira T255 <NUM> PEPET <NUM> dtex <NUM>). The top layer contained <NUM> gsm of eccentric bicomponent fibers (Trevira T-<NUM><NUM><NUM> dtex <NUM>). The binder, <NUM> gsm (Wacker Vinnapas <NUM>), was applied to the bottom (floor sweeping tool side) of the structure. The total weight of the structure was calculated to be <NUM> gsm.

Sample 10D included three layers. The bottom layer contained <NUM> gsm of cellulose (Golden Isles Leaf River <NUM>) and <NUM> gsm synthetic fibers (Trevira T255 <NUM> PEPET <NUM> dtex <NUM>). The middle layer contained <NUM> gsm of eucalyptus pulp (Suzano, untreated) and <NUM> gsm synthetic fibers (Trevira T255 <NUM><NUM> dtex). The top layer contained <NUM> gsm of eccentric bicomponent fibers (Trevira T-<NUM><NUM><NUM> dtex <NUM>). The binder, <NUM> gsm (Wacker Vinnapas <NUM>), was applied to the bottom (floor sweeping tool side) of the structure. The total weight of the structure was calculated to be <NUM> gsm.

The samples of Example <NUM> (Sample 10A, Sample 10B, Sample 10C, and Sample 10D) were tested and compared to commercially available products in a Tile Wetting Test the method of which is provided in Example <NUM>. A list of the samples tested is shown in Table <NUM>. The results are summarized in Table <NUM>.

Control samples A and B were tested. Samples K and L each had the same composition as the Sample <NUM> composition provided in Table <NUM>. Samples K and L were embossed between two pieces of spunlace. Samples C, E, F, H, K and L each had the same embossed pattern as Sample B. Samples D, G, I, and J used a different emboss pattern. Samples C, E, F, G, H, I and K used the same lotion as Sample B (expressed from commercially available wipes). Samples D, J, and L used a different lotion than Samples C, E, F, G, H, L and K (a multi-purpose floor cleaning lotion).

The results indicate that Samples C through L containing eucalyptus pulp retained more lotion than control Samples A and B. In particular, both Samples C through J including a layer containing eucalyptus pulp and Samples K and L used as a core product between spunlace had less percent average lotion loss than the control Samples A and B.

Sample 10C was further tested to evaluate the sample cleaning ability and ability to remove stains. Sample 10C was tested in a dry state and in a dry state with a tackifier (approx. <NUM> gsm) applied to a top layer (floor surface) of the material. The composition of Sample 10C is provided in Table <NUM>. Commercially available Stainmaster® Microfiber Cloth and Swiffer® Wet Jet - Disposable Mop were also tested. The results are summarized in Table <NUM>. Using a Gardner Straight-Line Washability Apparatus (WA-<NUM>, Model D16VF) operating at <NUM> pound of pressure and <NUM> cycles per minute, a <NUM> in. × <NUM> in. sample was cut and mounted on a scrubbing block. The apparatus was started and the number of cycles to remove each of five different stains from a vinyl tile (Armstrong Flooring <NUM> Feature Tile R627A) was recorded. A schematic of the testing apparatus is illustrated in <FIG>. To produce the stains, a vinyl tile was cut into a 4in. wide strip and five (<NUM>) <NUM>-inch ID O-rings were used to contain solutions while they dried on the vinyl tile. A solution (<NUM>) was added to the center of the O-ring every <NUM> hours until a total volume of <NUM> was added. Five different solutions were used, and stains therefrom tested, one solution per O-ring as described below. The solutions remained at room temperature for <NUM> hours until dry. The vinyl tile was then heated in an oven at <NUM> °F for <NUM> hour. Samples were then tested within <NUM>-<NUM> hours.

To perform the test, cleaning solution (approx. <NUM>) was added to each of the stains using a pipette. The same cleaning solution (approx. <NUM>) was poured onto the floor cleaning test pad with a graduated cylinder. Swiffer® Wet Jet Multi-Purpose Floor Cleaner Solution with Febreze® refill lavender vanilla and comfort scent was used for all samples.

As provided in Table <NUM>, Sample 10C (dry) and Sample 10C (dry with tackifier) showed improved results on average at removing orange juice stains as compared to the commercially available Stainmaster® Microfiber Cloth and Swiffer® Wet Jet - Disposable Mop.

In addition to the various embodiments depicted and claimed, the disclosed subject matter is also directed to other embodiments having other combinations of the features disclosed and claimed herein. As such, the particular features presented herein can be combined with each other in other manners within the scope of the disclosed subject matter such that the disclosed subject matter includes any suitable combination of the features disclosed herein. The foregoing description of specific embodiments of the disclosed subject matter has been presented for purposes of illustration and description. It is not intended to be exhaustive or to limit the disclosed subject matter to those embodiments disclosed.

Claim 1:
A unitary airlaid nonwoven material comprising three layers of fibers, the first layer being the top layer, the second layer being the middle layer, and the third layer being the bottom layer, wherein the first layer comprises synthetic fibers, the second layer comprises cellulose fibers and synthetic fibers, and the third layer comprises cellulose fibers and a high core bicomponent fiber having a core to sheath ratio that exceeds <NUM>:<NUM> in that the core forms more than <NUM>% by weight of the high core bicomponent fiber, wherein hardwood bonded natural cellulosic fibers having a coarseness in a range of from <NUM>/<NUM> to <NUM>/<NUM> are contained in the second layer or the third layer, wherein the synthetic fibers of the first layer comprise bicomponent fibers in an eccentric configuration, and wherein the high core bicomponent fiber comprises a polyethylene-based sheath and a core comprising a polymer having a melting point above about <NUM> and higher density than the polyethylene sheath, and wherein the synthetic fibers of the second layer comprise low core bicomponent fibers wherein the core forms less than <NUM>% and <NUM>% or more by weight of the low core bicomponent fiber.