The invention relates to a heat sink (1) having a main body (2) and a plurality of carbon-nanostructure-based fibres (CNB, 3), more particularly carbon nano tubes (CNT, 4) or graphene fibres, of which at least some are attached to the main body (2). According to the invention, the fibres (3, 4), by adhering to or supporting one another, form a volume structure (12), more particularly in the manner of cotton wool, felt or a spun yarn, or the fibres (3, 4) form loops (6) or a three-dimensional woven fabric.

An upper for an article of footwear may be at least partially formed with a knitted component. The knitted component may include a first knitted portion and a second knitted portion, where the first knitted portion at least partially forms at least one of a medial side, a lateral side, and a toe area of the upper, and where the second knitted portion forms a tongue area of the upper. The second knitted portion may include a first end and a second end where one of the first end is secured to the first knitted portion via a common knit structure.

A method for manufacturing a water-penetration-preventing double-layer fabric and a double-layer fabric. The double-layer fabric includes two surface layer textures and a cross-linked texture. The two surface layer textures can be respectively formed by a base yarn and a fusible yarn, or each of the two surface layer textures includes the base and fusible yarns. A melting point of the base yarn is higher than that of the fusible yarn, one of the surface layer textures is heated and pressed to melt the fusible yarn to form a barrier layer, the cross-linked texture cross-links the surface layer textures, a space between the surface layer textures is formed with the cross-linked texture provided with a yarn-stacked thickness by a tuck knitting or a transfer knitting, and an increased temperature of the surface layer texture without heating and pressing is not higher than a melting point of the fusible yarn.

Described are shoes having an upper, and at least one of an outer sole and a midsole connected to the upper. At least one of the outer sole and the midsole is formed of knitwear.

A system and a method for an energy harvesting and storage apparatus including a flexible substrate, an energy harvesting device disposed on the flexible substrate, the energy harvesting device is configured to convert mechanical energy into electrical energy, an energy storage device disposed on the flexible substrate and in electrical communication with the energy harvesting device and configured to receive and store the electrical energy from the energy harvesting device.

An article of apparel is disclosed that includes zones with a textile having a structure than changes or is otherwise modified by a physical stimulus, such as the presence of water or a temperature change, to modify a property of the textile. The zones may be along a center back area and/or side areas of the apparel, and the textile may increase in air permeability when exposed to water. In some embodiments, slits are formed in the textile.

A shear band and a non-pneumatic tire is described which includes a ground contacting annular tread portion; a shear band, and a connecting web positioned between a hub and the shear band. The shear band is preferably comprised of a three-dimensional spacer fabric having a first and second layer connected by connecting members. The three-dimensional spacer fabric has a defined depth. The three-dimensional spacer structure further includes a plurality of cells formed between the connecting members, and wherein one or more of the cells are filled with a filler material. The filler material may be foam or a thermoplastic elastomer.

Examples of a knitted or woven fabric with moisture management function are described, comprising a face fabric layer with a durable water repellency (DWR) additives forming a fabric outer surface that is hydrophobic and a back fabric layer comprising a second yarn that is highly hydrophilic forming a moisture regain core to absorb the moisture and spread it across on an inside surface of the back fabric layer. The outer (face) layer of the fabric is hydrophobic due to the added DWR additives to the first yarn while the inner (back) layer of the fabric is highly hydrophilic that absorbs and spreads the moisture across the inner side of the back layer so that it dries faster making the outer surface of the face fabric layer dry thus reducing the occurrence of water/liquid spots on the face layer outer surface.

A task is to provide a multilayer structured cloth and a fiber product which are excellent in lightweight properties for bulkiness, impressive soft texture, high cushioning properties, low draping properties, and sweat absorbing and quick drying properties, and the task is achieved by a multilayer structured cloth including front and back ground structure portions, a connecting yarn which connects the front and back ground structure portions to each other, and an insert yarn, wherein at least one of the front and back ground structure portions contains a crimped fiber or a spun yarn.

A warp-knitted capacitive touch sensor system includes conductive and non-conductive yarns using interlooped stitches that are interlaced, intertwined, and/or spliced into a single conductive pathway having only two connection points to the electronic interface device, across a desired width or length of the textile material.