A system for the treatment of microorganisms includes: a textile web having optical fibers in warp and/or weft woven with binding threads in warp and/or weft, each of the optical fibers having invasive alterations along the fiber and allowing the emission of light propagating in the fiber at these alterations; a light source arranged opposite one or both free ends of the optical fibers. The textile web includes metallic warp and/or weft threads woven with the binding threads, the metallic threads being based on a metal having a negative effect on the growth of microorganisms. The light source generates a light beam having at least one wavelength in the visible or ultraviolet spectrum.

A color-changing product includes a fabric. The fabric includes a first layer and a second layer. The first layer is arranged using at least one fiber. The at least one fiber includes (a) an electrically conductive core and (b) a coating disposed around and along the electrically conductive core. The second layer is printed onto the first layer. The second layer includes a foreground thermochromic pigment that is selectively activatable by providing an electrical current to the electrically conductive core of the at least one fiber to change at least one of a foreground color or a pattern of the second layer.

The invention addresses the problem of providing a cloth and a protective product, which are excellent not only in flame retardancy but also in protection performance against electric arcs, and can further be provided with any color appearance. As a means for resolution, in a cloth including a flame-retardant fiber, a UV absorber or carbon particles are contained in the cloth, and the cloth is configured to have a lightness index L-value of 25 or more.

The invention addresses the problem of providing a cloth and a protective product, which are excellent not only in flame retardancy but also in protection performance against electric arcs, and can further be provided with any color appearance. As a means for resolution, in a cloth including a flame-retardant fiber, a UV absorber or carbon particles are contained in the cloth, and the cloth is configured to have a lightness index L-value of 25 or more.

Multi-filament microcables are used in place of the traditional monofilament wires as the constituent elements of a woven or braided band. This enhances the function and manufacturability of such bands for various applications, such as orthopaedic applications including sternotomy closures.

Multi-filament microcables are used in place of the traditional monofilament wires as the constituent elements of a woven or braided band. This enhances the function and manufacturability of such bands for various applications, such as orthopaedic applications including sternotomy closures.

For a woven fabric (20) with an additional thread (30, 34) laid out in a zigzag shape, in order to ensure in certain cases that the zigzag thread (30, 34) has its zigzag tip (38) always at the same position over the length of the woven fabric, it is proposed that the weft thread (24) is introduced at certain points in the woven fabric (20) in a floating manner over a plurality of adjacent warp threads (21) and that the feed needle (32, 36) is introduced or inserted into the woven fabric (20) at least at one side of the zigzag laid cover thread (30, 34) at several laying points or at all laying points where the weft thread (24) is floating over several adjacent warp threads (21). The cover thread (30, 34) is positioned at the inside of the zigzag shape.

For example, provided is an RFID-bearing flexible material, in which an RFID is attached to a flexible material, the RFID includes an antenna portion, and the antenna portion is formed of a conductive linear body containing a carbon nanotube yarn.

A color-changing product includes a fabric. At least a portion of the fabric includes or is arranged using at least one of (i) a color-changing fiber or (ii) a color-changing yarn including the color-changing fiber. The color-changing fiber includes an electrically conductive core having a first tensile strength, a reinforcement core having a second tensile strength that is greater than the first tensile strength, and a coating disposed around and along the electrically conductive core and the reinforcement core. The coating includes a polymeric material having a color-changing pigment.

Fabrics and garments are disclosed that exhibit fire resistance. The fabric has yarn containing FR materials that provide for the fire resistance. The fabric is optionally dyed. This abstract is intended as a scanning tool for purposes of searching in the particular art and is not intended to be limiting of the present invention.