This document presents a novel method of manufacturing multilayered nonwoven fabrics consisting of submicron fibers, hydroentangled, meltfibrillated, and/or spunlaid web layers. The composite multilayered webs contain one or more submicron fiber webs placed between inner and outer layers of hydroentangled, meltfibrillated, and/or spunlaid web, forming a fabric that may be utilized in the manufacture of articles which serve as barriers, wipes or sorbent materials, or may have other potential applications. The created novel composite multilayered fabric may have increased loft, softness and bending length, may not be solely dependent upon an electrostatic charge to repel small particles and microbes, and may be formed from a broad selection of natural, synthetic, and recycled polymers, including petroleum- and plant-based, allowing polymer selection based on article lifecycle.

A composite fabric includes a film, a first fibrous layer, a fabric layer, and a second fibrous layer and one or more retaining members. The film has a first side and a second side. The first fibrous layer has a first side connected to the second side of the film and a second side. The fabric layer has a first side connected to the second side of the first fibrous layer and a second side. The second fibrous layer has a first side connected to the second side of the fabric layer and a second side. The film can be a non-heat shrinking film. The retaining members may be configured to contact a surface on which the composite fabric is placed and resist movement of the composite fabric relative to the surface where the retaining members include a corrosion inhibitor.

A nonwoven laminate, includes in order (A) to (F), a spunbond nonwoven layer (A) including fibres with polyethylene terephthalate (PET) and copolyester, and an optional spunbond nonwoven layer (B) including fibres, which include polyethylene terephthalate and copolyester, the nonwoven layer (B) having a higher copolyester content than nonwoven layer (A). A needled staple fibre nonwoven layer (C) includes monocomponent polyethylene terephthalate staple fibres (c1) and multicomponent staple fibres (c2), which include at least a polyethylene terephthalate component and a copolyester component. An optional spunbond nonwoven layer (D) includes fibres, with polyethylene terephthalate and copolyester, the nonwoven layer (D) having a higher copolyester content than nonwoven layer (E). A spunbond nonwoven layer (E) includes fibres with polyethylene terephthalate and copolyester. A nonwoven layer (F) includes monocomponent polyethylene terephthalate fibres and/or multicomponent fibres with at least a polyethylene terephthalate component and a copolyester component. All layers are melt-bonded to each other.

A composite system is described, comprising at least one carrier layer; at least one layer designed as a fire protection fleece; and at least one component for shielding electrical, magnetic and/or electromagnetic radiation. Furthermore, a method for its manufacture and use is described.

Provided are burn protective materials and methods for making the same, and more particularly, flame-retardant composites with high flame-resistant additives and aqueous water-based bonding systems, and specifically those including a) a meltable layer; b) a heat reactive material comprising: a polymer resin comprising an aqueous acrylic resin, expandable graphite, at least one flame retardant (FR) additive, and at least one polyhydroxy compound; and c) an additional layer disposed on the heat reactive material so that the heat reactive material is between the meltable layer and the additional layer; wherein the textile composite has an afterflame of less than about 2 seconds.

The present disclosure is generally directed to a fabric laminate for architectural coverings. The laminate generally includes a nonwoven layer laminated to oriented filaments. The nonwoven layer can be a wet laid nonwoven layer. The filaments can comprise continuous spunbond filaments. Optionally, the laminate can include a third layer of oriented yarns. In one aspect, the yarns can be oriented in the length direction while the polymer filaments can be oriented in the width direction.

A composite panel includes a polymer matrix and a plurality of reinforcing fibers encapsulated in the polymer matrix. The plurality of reinforcing fibers includes bast fibers having a predetermined bending length greater than 80 ?m and less than 2 mm.

The purpose of the present invention is to provide a sandwich structure that achieves both excellent heat radiation and excellent mechanical characteristics. To this end, the sandwich structure according to the present invention has the following configuration. That is, the sandwich structure has a core material (I) and fiber-reinforced materials (II) arranged on both surfaces of the core material (I), wherein at least one of the fiber-reinforced materials (II) includes a sheet-shaped heat conduction material (III) having an in-plane heat conduction ratio of 300 W/m.Math.K or more.

The present disclosure discloses a chenille carpet, comprising a three-dimensional breathable base layer (1), wherein a three-dimensional weaved layer (2) made of chenille threads is provided on the three-dimensional breathable base layer (1), and the chenille threads in the three-dimensional weaved layer (2) have a diameter not less than 1 cm. The chenille carpet according to the present disclosure has high breathability, is not easy to trap dirt, and is easy to clean.

A cover for vehicle interior components is provided. The cover includes a fabric sheet comprising a yarn composed of polyester microfibers. The fabric sheet has a first face and a second face wherein the first face is an A-side surface with separated and raised microfibers that provide a suede-like appearance and feel. A polyester backing layer is laminated to the fabric sheet.