A nonwoven fabric comprising extendable fiber and elastic fiber, wherein the nonwoven fabric comprises a first side having a plurality of protrusions and a plurality of recesses and a second side on the side opposite the first side, the proportion of extendable fiber in the protrusions on the first side is higher than the proportion of extendable fiber in the recesses on the first side, and the nonwoven fabric is coated with a hydrophilic agent, or the extendable fiber and elastic fiber comprise a hydrophilic agent, the nonwoven fabric has a water absorbing property represented by a water absorption height of at least 10 mm in a water absorption test, and a quick-drying property represented by a transpiration rate of at least 20 mass % in a transpiration test.

It is aimed to provide a wiring harness protection material utilized as a wiring harness protection member and having protection performance in a high-temperature and high-humidity environment and a wiring harness. A wiring harness 1 is formed by molding wiring harness protection materials 1 using a thermally moldable nonwoven fabric containing polyethylene terephthalate fibers having a weight-average molecular weight in a range of 10000 to 200000 into a wiring harness protection member 2 having a predetermined shape and covering a wire bundle 4 with the wiring harness protection member 2.

It is aimed to provide a wiring harness protection material utilized as a wiring harness protection member and having protection performance in a high-temperature and high-humidity environment and a wiring harness. A wiring harness 1 is formed by molding wiring harness protection materials 1 using a thermally moldable nonwoven fabric containing polyethylene terephthalate fibers having a weight-average molecular weight in a range of 10000 to 200000 into a wiring harness protection member 2 having a predetermined shape and covering a wire bundle 4 with the wiring harness protection member 2.

A nonwoven web material including fibers formed of a polyolefin and a polyester is disclosed. The fibers may include fine fibers produced by, for example, a meltblowing process. The polyolefin may be polypropylene and the polyester may be polylactic acid. The polylactic acid may be obtained and included by recycling scrap nonwoven material containing a polylactic acid component, hydrolyzing the polylactic acid component to reduce its viscosity, blending the hydrolyzed polylactic acid with a polyolefin resin, and melt-spinning the blended material to form fibers. A related process is disclosed.

A nonwoven web material including fibers formed of a polyolefin and a polyester is disclosed. The fibers may include fine fibers produced by, for example, a meltblowing process. The polyolefin may be polypropylene and the polyester may be polylactic acid. The polylactic acid may be obtained and included by recycling scrap nonwoven material containing a polylactic acid component, hydrolyzing the polylactic acid component to reduce its viscosity, blending the hydrolyzed polylactic acid with a polyolefin resin, and melt-spinning the blended material to form fibers. A related process is disclosed.

A moldable composite with high heat resistance and noise absorption properties utilizes nonwoven fabrics and a heat resistance additive. The composition that provides both superior acoustic performance and excellent flex modulus that may be utilized in automotive products and applications in interior and exterior structures. A blowing agent may be utilized to create micro porous cells in a polymer non-woven structure. The cells or voids make the material lighter and allow the material to have superior acoustic properties that are useful in automotive applications.

A moldable composite with high heat resistance and noise absorption properties utilizes nonwoven fabrics and a heat resistance additive. The composition that provides both superior acoustic performance and excellent flex modulus that may be utilized in automotive products and applications in interior and exterior structures. A blowing agent may be utilized to create micro porous cells in a polymer non-woven structure. The cells or voids make the material lighter and allow the material to have superior acoustic properties that are useful in automotive applications.

It relates to a beaded nonwoven membrane comprising polymeric nanofibers and at least one active agent, wherein the active agent has a water solubility equal to or lower than 33 mg/mL. It also relates to a process for the preparation of the beaded nonwoven membrane, and to its use in medical, and veterinary applications.

It relates to a beaded nonwoven membrane comprising polymeric nanofibers and at least one active agent, wherein the active agent has a water solubility equal to or lower than 33 mg/mL. It also relates to a process for the preparation of the beaded nonwoven membrane, and to its use in medical, and veterinary applications.

Polymeric articles including fibers, films, and solid surfaces may be produced with improved properties by embedding particles within the article. The particles may be any particle that imparts desired properties to the fiber, film, or solid surface. Methods of selecting the particle size based upon the desired properties of the article such as the fiber diameter, film thickness, efficacy such as antimicrobial activity of the article, and/or article compositions are also described. For example, fibers having improved antimicrobial, antiviral, and antifungal properties are described. The articles having antimicrobial, antiviral, and antifungal properties may comprise a plurality of particles comprising water insoluble copper compounds that release at least one of Cu+ ions and Cu++ ions upon contact with a fluid. The average particle size or the particle size range is selected based upon the diameter of the fiber or thickness of the film to be produced.