A method for producing a trim part includes the following steps: generating a surface covering, wherein a knitted semi-finished product is generated on a flat knitting machine; the knitted semi-finished product is washed; the washed knitted semi-finished product is heat set; and laminating, in particular press-laminating or compression-laminating, the generated surface covering onto a carrier part.

Electronic equipment may include structured fabric. Structured fabric may be used as a protective case or cosmetic cover for an electronic device, may be used to form a band that holds an electronic device against a user's body, or may be used to cover one or more openings in an electronic device. Structured fabrics may be soft and pliable while maintaining the ability to hold a given shape without added support. Structured fabric may be formed by laminating fabric such as warp-knit fabric with a stiffener such as polymer film. Structured fabrics may include openings through which signals such as optical or audio signals pass. To maintain the geometry and shape of the openings in the structured fabric without covering the openings, the stiffener and adhesive that are attached to the fabric may be cut to form a pattern of openings that align with the openings in the fabric.

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 provides cover systems for covering components of a cabin interior of a vehicle, such as an automobile, a train car, a bus, a boat, or an aircraft, among others. For instance, the cover systems may cover one or more of a seat and a floor, among others, of the cabin interior. The fabric cover systems may absorb or partially absorb one or more of low-frequency sounds, such as low-frequency noise emitted by an engine, and high-frequency sounds, among others. The fabric cover systems may absorb or partially absorb odor molecules. The fabric covering systems may include multiple layers. For instance, one of the layers may include activated carbon fibers. The activated carbon fibers may absorb or partially absorb one or more of sounds, liquids, and odors, among others.

A thermally protective composite material is provided, which can be used in making garments. The thermally protective composite material includes an outer layer of fabric/textile, an adhesive layer applied to the outer layer of fabric in a geometric pattern, and an elastic inner layer of fabric/textile, adhered in a stretched state, to the outer layer via the adhesive layer. The elastic inner layer, when in a relaxed state, causes the adhered outer layer to vault/bubble forming raised cavities according to the geometric pattern of the adhesive. When constructed into garments the thermally protective composite material can stretch between the relaxed state and the stretched state of the elastic inner layer.

A process for fabricating a three-dimensional, multi-layered fabric product with a moisture barrier is provided. A partially seamed inner lining fabric assembly having at least a two-dimensional shape is laminated with a membrane barrier film having flaps left un-laminated to cover at least one seam. The inner lining fabric assembly is further seamed and flaps of the of the membrane barrier film overlapped into contact with each other and sealed to provide a continuous moisture barrier. A process for fabricating a stretchable section of a garment with a moisture barrier is also provided. At least a section of a garment is formed from fibers arranged in a pattern having a direction of stretch in one direction and a three-dimensional surface texture such that a portion of the fibers protrude above another portion of the fibers. The stretchable section is stretched in the direction of stretch. Segments of a membrane barrier film are adhered to an outer edge of the protruding portion of the fibers while the section is stretched in the direction of stretch, leaving intermediate segments of the barrier film free from adherence to the section. In this way, the intermediate segments of the membrane barrier film include slack that folds up to form ruches when the section is in a relaxed state.

A method for manufacturing a flame-resistant textile material for protective clothing is characterized in that at least one textile layer is subjected to a treatment step wherein at least one fibre component is at least partially detached from the textile layer such that air chambers (5) are formed.

A protective cover includes a padding layer and at least one backing layer comprising a network of fiber-reinforced plastic (FRP) threads, wherein a surface of the at least one backing layer is substantially rectangular comprising a first side, and wherein a plurality of the FRP threads are arranged along a direction that is oblique relative to the first side.

The present invention provides multiple processes of making fabric composites using fabric and/or fiber waste, or virgin fabric or fiber as starting material and via a needle punching process. The fabric and/or fiber waste, or virgin fabric or fiber, are regenerated to form fabric composites for reuse.

A skin material includes: a design layer; and a base cloth layer. The design layer includes a surface layer and a foam layer. The base cloth layer includes a surface fabric and a back fabric, and a binding yarn that binds the surface fabric and the back fabric. The binding yarn is a thermoplastic resin fiber erected between the surface fabric and the back fabric to form a gap between the surface fabric and the back fabric. The foam layer and the surface fabric are joined. An interior material includes the skin material and a base material to which the skin material is attached. A method for producing the skin material includes joining the surface layer and the base cloth layer via a foamable adhesive to serve as the foam layer.