Embodiments of the present invention provide systems and methods for using nonwoven materials for evacuation slides, life rafts, life vests, and other life-saving inflatable devices. The nonwoven materials have a substrate layer with continuous filaments formed in various directions.

The invention concerns a process for preparing a ribbon of reinforcement strands or filaments associated on each of its faces with a polymeric binder, said ribbon having a given width substantially constant over its entire length, in which the strands or filaments extend in a direction parallel to the length of the ribbon, wherein it comprises the following steps: a) adjustment of the ribbon width to the desired width thanks to a dimensioning device, b) association of the ribbon on each of its faces with a polymeric binder allowing the assurance of a homogenous cohesion of the ribbon, such that the total weight of the binder does not exceed 25% of the total weight of the obtained ribbon,
as well as the ribbons obtainable by such a process.

Embodiments of the present disclosure relate generally to nonwoven substrate materials that find particular use in connection with evacuation slides, evacuation slide/rafts, life rafts, life preservers/vests, or other emergency flotation devices. Such devices are typically formed from woven substrates, but the present inventors have determined that using nonwoven substrates in connection with such devices can provide improved benefits. The nonwoven substrates further have a gas barrier formed thereon by using layer-by-layer (LBL) nanocoating technology.

The invention concerns a process for preparing a ribbon of reinforcement strands or filaments associated on each of its faces with a polymeric binder, said ribbon having a given width substantially constant over its entire length, in which the strands or filaments extend in a direction parallel to the length of the ribbon, wherein it comprises the following steps: a) adjustment of the ribbon width to the desired width thanks to a dimensioning device, b) association of the ribbon on each of its faces with a polymeric binder allowing the assurance of a homogenous cohesion of the ribbon, such that the total weight of the binder does not exceed 25% of the total weight of the obtained ribbon,
as well as the ribbons obtainable by such a process.

The present invention provides the composite material layer forming method of composite material container: wrap a continuous fiber around the surface of inner tank at a predetermined angle to form at least a layer of composite material, and tile an additive between composite material layers and/or inner surface and/or outer surface to prevent cracking along a fiber direction of the composite material layer.

The present disclosure provides an interior panel and a manufacturing method therefor. And the manufacturing method includes: a panel base part of the interior panel being heated to a first temperature, and the panel base part is made of composite material, and matrix of the composite material is a first material, reinforcement of the composite material is a second material, and the first temperature is at least a softening point of the first material; the heated panel base part and a panel surface part being stacked on a first mold for press-molding; and, the panel surface part includes a surface side section and a back side section, and the surface side section provides a surface of the interior panel, and the back side section is set to be on back side of the surface side section, and the back side section has a first material component made of first material.

The present disclosure relates to composites. One composite may include a resin and oxidized polyacrylonitrile fibers. The oxidized polyacrylonitrile fibers may be provided as a nonwoven fabric. An additional composite may include a resin and material scraps respectively including carbon fibers. The material scraps may be positioned to at least partially overlap one another and define a substantially continuous layer. The material scraps may be provided as a fabric and/or a plurality of loose fibers.

A hot press cushioning material (10) of the present invention includes, as a base material, a woven fabric layer (11) using bulky yarn (12) as at least one of the warp and weft, and a nonwoven fabric layer (14) placed on one surface side of the woven fabric layer (11), a part of the nonwoven fabric layer (14) being embedded in the woven fabric layer (11). A nonwoven fabric-resin composite layer (18) is formed in the opposite surface of the nonwoven fabric layer (14) from the woven fabric layer (11) by impregnation with resin (15). A woven fabric-rubber composite layer (19) is formed in the other surface of the woven fabric layer (11) by impregnation with rubber (16). The nonwoven fabric-resin composite layer (18) and the woven fabric-rubber composite layer (19) have voids (17) therein.

An electrolyte conductor (1) has a nonwoven fabric (2), onto which a plastic film (3) is laminated. A process is provided for the manufacture of the electrolyte conductor (1). An electrochemical gas sensor (10) is provided with such an electrolyte conductor (1). A gas-measuring device is provided with such a gas sensor (10).

A non-woven material including a base layer and one or more fiber cap layer. In example embodiments, the fiber cap layer can be (1) used as an adhesive layer to bond the base layer to another material, (2) molded in order to create a smooth film surface that reduces ice, mud and snow buildup in the automotive part, (3) molded to increase stability and reduce sagging in the automotive part, or (4) molded into an air flow resistant layer to increase sound absorption properties. The non-woven material can be heat-resistant, flame-resistant, water-resistant, and/or recyclable.