A woven fabric for use in a machine to produce a fiber web, such as a tissue fiber web, has a paper side formed by interwoven warp yarns and weft yarns. The paper side has a plurality of twill lines formed by neighboring flotations of warp yarns. The twill lines have an MD vector component in a machine direction and a CD vector component in a cross machine direction. At least some twill lines are diagonal, with a CD vector component being unequal to zero. The diagonal twill lines include first diagonal twill lines with CD vector components that have an opposite sign to the CD vector components of second diagonal twill lines. A sum of all CD vector components of the first diagonal twill lines is substantially balanced with a sum of all CD vector components of the second diagonal twill lines.

Provided is a security fabric having improved security and identification properties, the security fabric comprising security threads containing a fluorescent material, which has an intrinsic light emission characteristic under excitation light, wherein the security threads are included in warp threads, weft threads, or warp and weft threads, and a set number of security threads are included per unit area.

Provided is a security fabric having improved security and identification properties, the security fabric comprising security threads containing a fluorescent material, which has an intrinsic light emission characteristic under excitation light, wherein the security threads are included in warp threads, weft threads, or warp and weft threads, and a set number of security threads are included per unit area.

A woven fabric for use in a machine to produce a fiber web, such as a tissue fiber web. A paper side of the fabric has warp yarns and weft yarns interwoven in a weave pattern, and twill lines, each formed by neighboring warp yarn flotations. Each warp yarn flotation of the weave pattern that contributes to the formation of the twill lines passes over a first weft yarn, which passes over a first warp yarn that directly neighbors the warp yarn flotation on a first side and passes below a second warp yarn that directly neighbors the warp yarn flotation on a second side opposite the first side. The warp yarn flotation also passes over a second weft yarn that directly neighbors the first weft yarn, and the second weft yarn passes below the first warp yarn and over the second warp yarn.

A garment may include a first woven component, a second woven component, a space between the first and second woven components defining a channel filled with a fill material, and a third woven component extending such that the first and second woven components are woven together where there is no channel. The channel may be filled with a filler material. Multiple channels may be provided such that they form a zoned pattern in the garment.

A respiratory mask including a mask fabric body (1), and one or more holding straps (3) for holding the mask body to the face of a user, the mask body being made of a woven fabric having weft yarns and warp yarns, the weft and warp yarns having a count comprised between 10 and 1100 den, the warp density being between 14-130 warps/cm, the weft density being between 12-70 wefts/cm, wherein at least part of the body is provided with a liquid-repellent crosslinked polymer.

Aspects herein are directed to a woven, breathable textile. The textile comprises a first woven zone and a second woven zone, where the first and second woven zones are integrally woven such that a particular warp yarn extends through both the first woven zone and the second woven zone of the textile. The first woven zone comprises a first woven layer and a second woven layer with a space or void formed between the first and second woven layers. The second woven zone comprises a single woven layer comprising a plurality of apertures formed through the weaving process, where each aperture is located at the center of a repeating pattern of interlacings.

A fabric can comprise yarns comprising less than about 30 denier total and less than about 10 denier per filament; a density of greater than about 177 yarns per cm.sup.2; and a thickness of less than about 3.2 mil. The fabric can further comprises a weight of less than about 60 g/m.sup.2. The fabric can have performance characteristics equivalent to or greater than those in conventional implantable fabrics. A method of making such a fabric can include twisting together filaments into a multifilament yarn; passing adjacent yarns into a loom in parallel so as to allow the yarns to be woven together more closely; maintaining a consistent tension on the yarns during placement of the yarns on a loom beam and during weaving; and or subjecting the fabric to increased heat and pressure so as to compress the yarns more tightly.

A garment may include a first woven component, a second woven component, a space between the first and second woven components defining a channel filled with a fill material, and a third woven component extending such that the first and second woven components are woven together where there is no channel. The channel may be filled with a filler material. Multiple channels may be provided such that they form a zoned pattern in the garment.

A double-face fabric having elastic properties in its warp direction and provided with hook-and-loop properties, formed by the weaving of warp yarns and of weft yarns. The warp yarns are of four different types worked in different weaves with respect to the weft yarns, respectively: elastic yarns (A) worked in a taffeta weave; core yarns (B), formed of synthetic yarns texturized by false twist on the face, worked in a plain weave alternating with surface floats and having a linear strand density in the range from 10 to 25 dtex; core yarns (C) on the back side, formed of multifilament synthetic yarns, having a linear strand density in the range from 0.3 to 1.7 dtex, worked in a rep weave, alternating floats of great length on the back side and short binding areas on the face side, binding yarns, exclusively formed of thermo-adhesive synthetic yarns, having a melting point in the range from 80° C. to 160° C., worked in a plain weave.