In one aspect of the present subject matter, a method of forming a linear panel includes drawing a multi-layer panel material assembly having differing inner and outer material layers along a processing path. The method also includes heating the panel material assembly. In addition, the method includes forming the heated panel material assembly into a desired shape as the assembly is drawn along the processing path. Additionally, in another aspect of the present subject matter, a linear panel includes a body formed from a multi-layer panel material assembly having differing inner and outer material layers.

The invention relates to a liquid applied roofing membrane which contains a textile with a compatibility coating covering essentially all of the fibers of the textile forming a coated textile, a first membrane, and a second membrane. The textile contains a plurality of yarns, the yarns comprising a plurality of fibers. The compatibility coating has a weight of between about 0.5 and 10% of the weight of the textile and contains a first chemistry. The first membrane contains a second chemistry and is located on the first side of the textile, forms the lower surface of the roofing membrane, and covers at least a majority of the second side of the textile. The second membrane contains a third chemistry and is located on the second side of the textile. The first, second, and third chemistries comprise the same class of polymeric material.

To provide a method for manufacturing a novel molded article using a commingled yarn and a composite material using a commingled yarn. The method for manufacturing a molded article, includes disposing a commingled yarn containing a continuous reinforcing fiber and a continuous thermoplastic resin fiber on a part of a surface of a prepreg, the prepreg containing continuous reinforcing fibers paralleling at least unidirectionally, and a thermosetting resin impregnated between the continuous reinforcing fibers, and heat-processing the prepreg with the commingled yarn.

Disclosed is a method for producing a prepreg, the prepreg having: a reinforcing fiber layer including reinforcing fibers and a resin composition containing component (A), component (B), and component (C), the reinforcing fibers being impregnated with the resin composition in between the fibers; and a surface fiber layer provided on the surface of the reinforcing fiber layer and including a fabric including polyamide fibers and a resin composition containing component (A), component (B), and component (C), the polyamide fibers being impregnated with the resin composition in between the fibers. The method for producing a prepreg includes a disposition step of disposing the fabric on the surface of a reinforcing fiber base material and an impregnation step of supplying a resin composition to the reinforcing fiber base material and impregnating the reinforcing fibers with the resin composition in between the fibers.

The present invention discloses a novel one-piece sandwich structured knitted waterproof upper with rubber topline, comprises, an upper body, comprising a surface layer, a waterproof and breathing layer and a liner layer, the surface layer is made from yarn, an inner side of the surface layer is provided with evenly distributed yarn meshes, the liner layer is made from a polyester fiber layer, an inner side of the polyester fiber layer is provided with a mildew proof and antibacterial layer; an end of the upper body is provided with a topline, a flexible rubber band is provided at an inner side of the topline; and ventilating pores are provided at an inner side of the surface layer. By configuring the upper body to contain materials such as the polyester fiber layer with waterproof function and cooperating with weaving in different knitting intensities, air ventilation is good compared with leather uppers.

Provided is a dry cosmetic sheet including: a dry support formed of a mesh, the mesh being made of a woven silver yarn; and a dry membrane laminated on the support, the dry membrane being capable of being attached to a users skin, and the dry membrane being formed of a fiber web, the fiber web being formed of accumulated electrospun fibers, each of the electrospun fibers being formed of a single homogeneous mixture containing a water-soluble polymer, a water-insoluble polymer, and a functional material for skin care in a dry state, the functional material being capable of releasing from the fiber by dissolution of the water-soluble polymer when the dry cosmetic sheet is moisturized. Each of the electrospun fibers has a homogenous distribution of the water-soluble polymer, the water-insoluble polymer, and the functional material.

The present invention relates to a structure for producing ballistic protection which combines high levels of performance in terms of stopping bullets and reducing trauma with great flexibility and breathability. A ballistic laminate comprising joined together unidirectional layers is produced. The ballistic laminate provided by the present invention is preferably produced by superposing at least two layers of ballistic yarns 101 and 103, arranged unidirectionally according to directions inclined relative to one another by approximately 90° (+/−10°). Each layer comprises a plurality of fibres arranged unidirectionally according to a substantially mutually parallel direction (+/−10°).

A hybrid fiber-reinforced composite material according to an aspect of the present disclosure may comprise a first continuous fiber layer, a long fiber layer laminated on one surface of the first continuous fiber layer, and a second continuous fiber layer laminated on one surface of the long fiber layer, and may further comprise at least one of a first thermosetting resin laminated on the other surface of the first continuous fiber layer and a second thermosetting resin laminated on one surface of the second continuous fiber layer.

Example implementations include a textile apparatus for transporting perspiration and heat, the textile apparatus including a substantially planar and heat-conducting substrate including at least one recess, and a textile film including one or more fibers disposed in contact with at least one substantially planar surface of the substrate and at least one surface of the recess. Example implementations also include a method of manufacturing a textile apparatus for transporting perspiration and heat, the method including forming a nanofiber solution, extruding one or more nanofibers from the nanofiber solution, forming one or more recesses in a substantially planar surface of a substrate, and integrating one or more of the nanofibers with the substantially planar surface of the substrate and at least one surface of the recesses.

An armor and a method of forming an armor. The armor comprising a lamination comprising a plurality of alternating stacks of fabric layers. The alternating stacks of fabric layers include a woven fabric layer and a unidirectional fabric layer.