The disclosure provides a compression garment (68) formed of a stretchable fabric (10) with a uniform, i.e. constant, elasticity but in which the compression garment provides different degrees of garment compression when worn by a wearer due to geometric cuts (6, 8) made to the fabric to form one or more fabric panels (2, 4) that extend the entire length of the circumferential portion (60) of the garment. The circumferential portion surrounds a wearer's body part (66) and includes degrees of compression that vary at different locations (12, 14, 16, 18, 20, 22, 24, 26), along the axial direction (62). The geometric cuts produce non-linear edges (6A, 6B, 8A, 8B) and are made to provide different circumferential lengths (12F, 14F, 16F, 18F, 20F, 22F, 24F, 26F) of fabric that produce desired compression levels at various axial locations, and are calculated using formulas and algorithms that take into account various factors relating to the fabric and the garment being formed.

The disclosure provides a compression garment (68) formed of a stretchable fabric (10) with a uniform, i.e. constant, elasticity but in which the compression garment provides different degrees of garment compression when worn by a wearer due to geometric cuts (6, 8) made to the fabric to form one or more fabric panels (2, 4) that extend the entire length of the circumferential portion (60) of the garment. The circumferential portion surrounds a wearer's body part (66) and includes degrees of compression that vary at different locations (12, 14, 16, 18, 20, 22, 24, 26), along the axial direction (62). The geometric cuts produce non-linear edges (6A, 6B, 8A, 8B) and are made to provide different circumferential lengths (12F, 14F, 16F, 18F, 20F, 22F, 24F, 26F) of fabric that produce desired compression levels at various axial locations, and are calculated using formulas and algorithms that take into account various factors relating to the fabric and the garment being formed.

To provide a towel product capable of maintaining features of honeycomb weave of the conventional technique as well as providing improved water absorbency, lightness, and a good touch feeling more than those of the towels produced by the conventional technique. The towel of the present invention basically has a typical honeycomb weave structure. A first feature thereof is to use hollow yarns having a hollow ratio of a range between 30% and 60%. A shape of hollow yarns can be maintained. With the above described structure, the water absorbency, the lightness, the good touch feeling, and a drying property can be improved. A second feature is to use hollow yarns made by twisting fibers of raw cottons having an effective fiber length of a range between 25 mm and 42 mm. This contributes to maintaining of the durability.

A novel woven fabric is provided wherein preferably two unidirectional mutually offset and at least partly overlapping layers of tape-like warps interlace with tape-like wefts, at least some being fibrous tapes, that are incorporated individually in either non-overlapping manner or in a mutually offset and overlapping manner relative to other weft tapes. Such a woven fabric is without see-through gaps at the areas/sites encircled by intersecting tape-like warps and wefts, and also delamination resistant. It is particularly suitable for composite material, ballistic mitigation, and similar applications.

The heat resistant separation fabric for use as tool cover in glass processing comprises heat resistant yarns (100). The heat resistant yarns comprise a core (110) and at least one wrap yarn (123, 125). The core is a core yarn. The core yarn is a multifilament glass yarn. The at least one wrap yarns (123, 125) comprises stainless steel fibers. The core yarn is present in the heat resistant yarn without crimp. The at least one wrap yarn is wrapped around the core yarn.

A seamless double-woven fabric for filling down includes a first fabric layer including first warps and first wefts, a second fabric layer including second warps and second wefts, and a coupling part to partition a down filling part formed between the first and second fabric layers into down filling spaces. The first warp and the second warp are formed so as to be crossed to each other one time or at least two times through a coupling weft. If the number of the coupling wefts is 2n, wherein n is an integer of 1 or more, the first and second fabric layers are arranged to be crossed about the coupling part. If the number of the coupling wefts is 2n+1, wherein n is an integer of 0 or more, the first and second fabric layers are arranged not to be crossed.

A seamless double-woven fabric for filling down includes a first fabric layer including first warps and first wefts, a second fabric layer including second warps and second wefts, and a coupling part to partition a down filling part formed between the first and second fabric layers into down filling spaces. The first warp and the second warp are formed so as to be crossed to each other one time or at least two times through a coupling weft. If the number of the coupling wefts is 2n, wherein n is an integer of 1 or more, the first and second fabric layers are arranged to be crossed about the coupling part. If the number of the coupling wefts is 2n+1, wherein n is an integer of 0 or more, the first and second fabric layers are arranged not to be crossed.

A method includes forming a multi-pick yarn package through winding multiple oriented yarns onto a spool, with the multiple oriented yarns serving as weft yarns forming adjacent substantially parallel yarns wound together. Each of the multiple oriented yarns is formed through drawing each of multiple yarns from a corresponding supply package. The method also includes, using the multi-pick yarn package, simultaneously inserting the weft yarns in a single pick insertion event of a pick insertion apparatus of a loom apparatus in which the simultaneously inserted weft yarns are to be conveyed through a set of warp yarns to produce an incremental length of a woven textile fabric.

A method includes forming a multi-pick yarn package through winding multiple oriented yarns onto a spool, with the multiple oriented yarns serving as weft yarns forming adjacent substantially parallel yarns wound together. Each of the multiple oriented yarns is formed through drawing each of multiple yarns from a corresponding supply package. The method also includes, using the multi-pick yarn package, simultaneously inserting the weft yarns in a single pick insertion event of a pick insertion apparatus of a loom apparatus in which the simultaneously inserted weft yarns are to be conveyed through a set of warp yarns to produce an incremental length of a woven textile fabric.

A touch-sensitive textile device that is configured to detect the occurrence of a touch, the location of a touch, and/or the force of a touch on the touch-sensitive textile device. In some embodiments, the touch-sensitive textile device includes a first set of conductive threads oriented along a first direction, and a second set of conductive threads interwoven with the first set of conductive threads and oriented along a second direction. The device may also include a sensing circuit that is operatively coupled to the first and second set of conductive threads. The sensing circuit may be configured to apply a drive signal to the first and second set of conductive threads. The sensing circuit may also be configured to detect a touch or near touch based on a variation in an electrical measurement using the first or second set of conductive threads.