A stretchable fabric signal path may include a conductive strand located between first and second outer fabric layers. The outer fabric layers may be formed from intertwined strands of elastic material. The conductive strand may have a wavy shape to accommodate stretching of the stretchable fabric signal path. First and second inner fabric layers may be located between the outer stretchable fabric layers. The inner fabric layers may be formed from intertwined strands of non-elastic material. The inner fabric layers may have strands that are intertwined with the outer fabric layers to serve as anchor points for maintaining the shape of the conductive strand as the stretchable fabric signal path expands and contracts. The outer fabric layers and inner fabric layers may be woven. The conductive strand may convey electrical signals such as audio signals, power signals, data signals, or other suitable signals.

It is described a knitted/woven fabric with moisture management function comprising a first fabric layer having a first yarn and a second yarn knitted together to form a first layer being semi-hydrophilic or hydrophobic (comprising of lower moisture regain fibers), a second fabric layer comprising a third yarn and a fourth yarn knitted together to form the second fabric layer, the second fabric layer being fully hydrophilic (comprising of higher moisture regain fibers), wherein the first fabric layer has a moisture regain lower than the moisture regain of the second fabric layer providing a hydrophilic gradient between the first fabric layer and the second fabric layer of the knitted fabric pushing moisture through the first fabric layer in contact with the wearer's skin and out through the second fabric layer.

It is described a knitted/woven fabric with moisture management function comprising a first fabric layer having a first yarn and a second yarn knitted together to form a first layer being semi-hydrophilic or hydrophobic (comprising of lower moisture regain fibers), a second fabric layer comprising a third yarn and a fourth yarn knitted together to form the second fabric layer, the second fabric layer being fully hydrophilic (comprising of higher moisture regain fibers), wherein the first fabric layer has a moisture regain lower than the moisture regain of the second fabric layer providing a hydrophilic gradient between the first fabric layer and the second fabric layer of the knitted fabric pushing moisture through the first fabric layer in contact with the wearer's skin and out through the second fabric layer.

A process of forming the fiber preform includes providing a substrate, applying a first layer of a fiber bundle to the substrate in a predetermined pattern having a principal orientation, stitching the first layer of the fiber bundle to the substrate using a thread, building up subsequent layers of the fiber bundle from the first layer, and stitching each of the subsequent layers to a preceding layer using the thread. A process of forming a unitary reinforced composite material includes the fiber preform. The process of forming a unitary reinforced composite component includes placing the fiber preform a mold platen, heating the perform to promote fusion of the thermoplastic fibers therein, cooling the perform until solidified with contours of the component, and removing the vehicle component from the mold platen.

A process of forming the fiber preform includes providing a substrate, applying a first layer of a fiber bundle to the substrate in a predetermined pattern having a principal orientation, stitching the first layer of the fiber bundle to the substrate using a thread, building up subsequent layers of the fiber bundle from the first layer, and stitching each of the subsequent layers to a preceding layer using the thread. A process of forming a unitary reinforced composite material includes the fiber preform. The process of forming a unitary reinforced composite component includes placing the fiber preform a mold platen, heating the perform to promote fusion of the thermoplastic fibers therein, cooling the perform until solidified with contours of the component, and removing the vehicle component from the mold platen.

The present invention relates to a body and hair towel comprising a microfiber interior layer and a silk exterior layer. The novel towel is comprised of a plurality of double layered capsules, wherein each capsule has an interior layer of microfiber material and an exterior layer of silk material. The exterior silk layer on the capsules provides an extremely smooth texture to the towel, thereby making the towel comfortable and convenient to use by people having dry skin, skin conditions or the like, and may also be comfortably used on hair without affecting the health of hair and skin of the users.

The present invention relates to a body and hair towel comprising a microfiber interior layer and a silk exterior layer. The novel towel is comprised of a plurality of double layered capsules, wherein each capsule has an interior layer of microfiber material and an exterior layer of silk material. The exterior silk layer on the capsules provides an extremely smooth texture to the towel, thereby making the towel comfortable and convenient to use by people having dry skin, skin conditions or the like, and may also be comfortably used on hair without affecting the health of hair and skin of the users.

A woven textile structure is formed by weaving a first woven layer including first yarns and weaving a second woven layer including first yarns, where the woven layers are arranged in a stacked manner and are separated from each other. During the weaving of the first and second woven layers, second yarns are inserted along an intermediate span in the weft direction of the woven textile structure, where the second yarns are elongated to an elongated length during the insertion in the weft direction. First yarns of the first woven layer are interlaced with first yarns of the second woven layer and a second yarn of the intermediate span at a plurality of interlacing locations along the woven textile structure so as to define stitches at each interlacing location, where each stitch joins the first woven layer with the second woven layer.

A manufacturing process of a fibrous preform for a composite material includes creating a fibrous texture by three-dimensional or multilayer weaving between a plurality of weft layers and warp layers, the fibrous texture including an extra-thick portion having a sacrificial portion and a useful portion adjacent to the sacrificial portion in the warp direction, the sacrificial portion, placing the fibrous texture in a forming toolset, shaping the fibrous texture so as to obtain a fibrous preform having a sacrificial portion and an adjacent useful portion, removing the sacrificial portion from the fibrous preform. When weaving the fibrous blank, one or more expansion elements are inserted into the weft layers located at the core of the sacrificial portion of the fibrous texture. Each expansion element has a cross-section greater than the cross-section or count of the weft threads or strands present in the useful portion.

A fiber structure body includes a several fiber layers stacked in a stacking direction and has a multi-axial orientation that includes axial-force directional yarns, orthogonal directional yarns, and intersecting yarns. The fiber structure body includes a flat plate portion and a bend portion that is bent to the flat plate portion and includes a surface intersecting with a surface of the flat plate portion. The axial-force directional yarns are made of continuous fiber of reinforced fiber. Of yarns that form the bend portion and are other than the axial-force directional yarns, yarns that form at least one axis of the bend portion are provided by spun yarns made of discontinuous fiber.