Provided is heartwood for a sandwich panel, comprising: a first polyester-based fiber which is a monocomponent fiber; and a second polyester-based fiber which is a sheath-core type bicomponent fiber. Also provided is a sandwich panel comprising: heartwood derived from the heartwood for a sandwich panel; and a surface material disposed on the sides of the heartwood. Further provided is a method for producing the sandwich panel, comprising: a step of mixing the first polyester-based fiber which is a monocomponent fiber and the second polyester-based fiber which is a sheath-core type bicomponent fiber; a step of producing the heartwood from the mixed fibers by a dry production process; and a step of heating and pressuring the heartwood.

An abrasion resistant wipe and a manufacturing method therefor. The abrasion resistant wipe has an upper layer and a lower layer each being a meltblown fiber web and a middle layer being wood pulp fiber web; wherein the meltblown fiber web comprises meltblown fibers with fiber surface being high melting point resin and meltblown fibers with fiber surface comprising low melting point resin; there is a difference of ≥20° C. between melting point of the low melting point resin and melting point of the high melting point resin; percentage of the meltblown fibers with fiber surface comprising low melting point resin in total fibers of the meltblown fiber web is greater than 5%; the meltblown fibers of the meltblown fiber web penetrate in the wood pulp fiber web.

A multilayer nonwoven fabric includes: an elastic nonwoven fabric containing a specific low crystalline polypropylene; and a mixed fiber spunbonded nonwoven fabric disposed on at least one surface of the elastic nonwoven fabric, wherein the mixed fiber spunbonded nonwoven fabric contains a long fiber of a thermoplastic elastomer (A) and a long fiber of a thermoplastic elastomer (B) other than the thermoplastic elastomer (A), in a ratio of 10 to 90% by mass:90 to 10% by mass ((A):(B), with the proviso that (A)+(B)=100% by mass).

A composite acoustic layer is provided including a first nonwoven material consisting of filaments having a linear density in the range of 2 to 25 dtex, wherein the first nonwoven material is a thermally bonded nonwoven material, and including a second nonwoven material connected to the first nonwoven material, wherein the second nonwoven material is a carded staple fiber nonwoven, and wherein the composite acoustic layer has a total weight in the range of 100 g/m.sup.2 to 500 g/m.sup.2.

Nonwoven materials having at least one layer comprising high core bicomponent fibers are provided. The nonwoven materials can have multiple layers and are suitable for use in a variety of applications, including in absorbent products. Such nonwoven materials can be patterned to create a three-dimensional topography including indentations formed of valleys and ridges. The nonwoven materials can have improved resiliency and strength and can retain their structure under wetted conditions and after tension and compression. The nonwoven materials can further facilitate the transfer of the liquid through the nonwoven material for improved liquid distribution and can also have improved liquid retention properties.

A nonwoven fabric layered body, including: an elastic nonwoven fabric; and an extensible spunbond nonwoven fabric that is disposed on at least one surface side of the elastic nonwoven fabric and that has a degree of maximum load elongation of 50% or more in at least one direction, the nonwoven fabric layered body satisfying the following (1) and (2). (1) The elastic nonwoven fabric includes a resin composition containing a specific low-crystalline polypropylene, and an -olefin copolymer A containing an ethylene-derived constitutional unit and a propylene-derived constitutional unit, and having a melting point of 100 C. or more and a crystallization degree of 15% or less. (2) The resin composition contains from 5 parts by mass to 50 parts by mass of the -olefin copolymer A with respect to 100 parts by mass of the resin composition.

Disclosed is a fluid absorbent bed pad suitable for absorbing bodily fluids of a patient. The pad includes a backing layer comprising a first polymeric fiber and a second polymeric fiber, the second polymeric fiber being relatively tacky relative to the first polymeric fiber and being present in said backing layer in an amount relatively smaller than the amount of said first fiber and comprising a bicomponent fiber. The presence of the second polymeric fiber will impart a tacky nature to the backing to resist slipping and bunching of the bed pad.

Nonwoven materials having at least one layer comprising high core bicomponent fibers are provided. The nonwoven materials can have multiple layers and are suitable for use in a variety of applications, including in absorbent products. The nonwoven materials can have improved resiliency and strength and can retain their structure under wetted conditions and after tension and compression.

A laminated sound absorption member including a plurality of fiber layers and a base material layer positioned between the fiber layers, wherein the laminated sound absorption member is characterized in that: the laminated sound absorption member includes at least two fiber layers; the fiber layers comprise fibers having an average fiber diameter of at least 500 nm and less than 5 m, and have a basis weight of 10-500 g/m.sup.2, a ventilation rate of 950 m/Pa.Math.s or less, and a thickness of less than 2.9 mm; and the base material layer is at least one selected from the group consisting of non-woven fabrics and woven fabrics, and has a basis weight of 80 g/m.sup.2 to 800 g/m.sup.2 and a thickness of 2.9 mm to 20 mm.

Wheel arch for a motor vehicle with a wheel arch housing component for at least partially delimiting the wheel arch for a vehicle wheel of the motor vehicle, and with a wheel arch lining which is arranged on the surface of the wheel arch housing component facing the wheel and extends at least partially along this surface, the wheel arch lining having at least one support layer and one fiber layer, wherein the support layer forms the outer side of the wheel arch lining facing the wheel and the fiber layer is arranged between the wheel arch housing component and the support layer and the support layer and the fiber layer are thermally bonded to one another and formed into a wheel arch lining and wherein at least 50%, preferably at least 65%, preferably at least 80% of the surface of the fiber layer is in contact with the wheel arch housing component.