Provided is a multiple woven gauze fabric capable of controlling the degree of wrinkling according to use. A double woven gauze fabric is formed by stacking a front surface gauze structure A and a back surface gauze structure B. The front surface gauze structure A and the back surface gauze structure B are formed, and the front surface gauze structure A and the back surface gauze structure B are joined, as appropriate. The front surface gauze structure A is composed of a non-twist yarn, and the back surface gauze structure B is composed of a hollow yarn. That is, a gauze structure composed only of twisted yarn (solid yarn) is not included. The degree of wrinkling is controlled by considering the hollow rate of the hollow yarn.

Described herein is a pillar knitted crop netting comprising widely spaced knitted pillars and crop netting materials comprising a region(s) having such construction. Also described herein are crop nettings comprising yarns defining apertures to form the netting wherein said apertures have a plurality of sides formed by yarn sections and at least one of those yarn sections may be relatively slack when the netting is held taut in lengthwise and widthwise directions. The above nettings may have advantageous hail passage performance.

Described herein is a pillar knitted crop netting comprising widely spaced knitted pillars and crop netting materials comprising a region(s) having such construction. Also described herein are crop nettings comprising yarns defining apertures to form the netting wherein said apertures have a plurality of sides formed by yarn sections and at least one of those yarn sections may be relatively slack when the netting is held taut in lengthwise and widthwise directions. The above nettings may have advantageous hail passage performance.

A fabricated part for a high temperature operation including a non-metallic substrate formed of a polymer fabric of woven non-absorbent polymer filament. The substrate is heat-resistant and heat set at a temperature that is above a predetermined operating temperature of an operation of the fabricated part. The heat setting pre-shrinks/heat stabilizes the material, thereby reducing failure during use in high temperature and/or wet applications. The substrate is useful as an endless belt and other applications. The invention further includes an apparatus with a heating device configured to operate at the predetermined operating temperature, and the fabricated part within or extending through the heating device.

A textile part is configured for producing a composite-material element (11) or a composite-material body (12). The textile part (10) has a reinforcing system (15) including reinforcing warp threads (16) and reinforcing weft threads (17), and a binding system (25) with binding warp threads (27) and binding weft threads (26). The reinforcing system (15) has at least one first portion (20), into which the reinforcing threads (16, 17) are interwoven with one another directly for binding to facilitate withstanding high mechanical. The reinforcing system (15) also has at least one second portion (21), in which the reinforcing threads (16, 17) form binding-free crossover locations (22) preferably laid on one another in a drawn-out state to constitute a laid structure surrounded by the binding threads (26, 27). The laid structure of the reinforcing system (15), ensures particularly good draping and deformation capability at this location of the composite material.

A textile part is configured for producing a composite-material element (11) or a composite-material body (12). The textile part (10) has a reinforcing system (15) including reinforcing warp threads (16) and reinforcing weft threads (17), and a binding system (25) with binding warp threads (27) and binding weft threads (26). The reinforcing system (15) has at least one first portion (20), into which the reinforcing threads (16, 17) are interwoven with one another directly for binding to facilitate withstanding high mechanical. The reinforcing system (15) also has at least one second portion (21), in which the reinforcing threads (16, 17) form binding-free crossover locations (22) preferably laid on one another in a drawn-out state to constitute a laid structure surrounded by the binding threads (26, 27). The laid structure of the reinforcing system (15), ensures particularly good draping and deformation capability at this location of the composite material.

The invention relates to a medical device (20,21) for supporting at least one region of the body comprising at least one textile panel (26,27) having a longitudinal direction (L) and a transversal direction (T) arranged so as to encircle all or part of said region of the body to be supported. Said textile panel (26,27) comprises a woven textile strip, or several woven textile strips (1,28,29) at least partially superposed, said woven strip or said woven strips (28,29) each having a warp direction (C) and a weft direction (t), and comprising weft threads (2), first elastic warp threads (3), second non-elastic warp threads (4), and third warp threads (5), said first warp threads (3) and said second warp threads (4) being woven according to a leno shed the second warp threads forming the doup threads. Furthermore, said textile panel (26,27) is elastic in the longitudinal direction (L) and has a force in the longitudinal direction (L) which is greater than or equal to 500 cN/cm, to achieve an elongation equal to 30%.

The invention relates to a medical device (20,21) for supporting at least one region of the body comprising at least one textile panel (26,27) having a longitudinal direction (L) and a transversal direction (T) arranged so as to encircle all or part of said region of the body to be supported. Said textile panel (26,27) comprises a woven textile strip, or several woven textile strips (1,28,29) at least partially superposed, said woven strip or said woven strips (28,29) each having a warp direction (C) and a weft direction (t), and comprising weft threads (2), first elastic warp threads (3), second non-elastic warp threads (4), and third warp threads (5), said first warp threads (3) and said second warp threads (4) being woven according to a leno shed the second warp threads forming the doup threads. Furthermore, said textile panel (26,27) is elastic in the longitudinal direction (L) and has a force in the longitudinal direction (L) which is greater than or equal to 500 cN/cm, to achieve an elongation equal to 30%.

A fabric (10) for use in composite materials having a reinforcing system (11) made of reinforcing warp threads (13) and reinforcing weft threads (14), which are placed on top of one other in two different reinforcing layers (16), (17). A binding system (12) of binding warp threads (20) and binding weft threads (21) is formed from a binding yarn (30) with a lower yarn count than the reinforcing yarn (15). The reinforcing system (11) is enclosed between the binding warp threads (20) on the one side and the binding weft threads (21) on the other side, and thus, held in place at binding points (22). At each binding point (22), a binding warp thread (20) is guided and held between a stationary warp thread (25) and a regular warp thread (24) of a warp thread pair (23) of binding warp threads (20). Between two adjacent binding points of a warp thread pair (23), the stationary warp thread (25) and the regular warp thread (24) have intersecting points (26).

A fabric (10) for use in composite materials having a reinforcing system (11) made of reinforcing warp threads (13) and reinforcing weft threads (14), which are placed on top of one other in two different reinforcing layers (16), (17). A binding system (12) of binding warp threads (20) and binding weft threads (21) is formed from a binding yarn (30) with a lower yarn count than the reinforcing yarn (15). The reinforcing system (11) is enclosed between the binding warp threads (20) on the one side and the binding weft threads (21) on the other side, and thus, held in place at binding points (22). At each binding point (22), a binding warp thread (20) is guided and held between a stationary warp thread (25) and a regular warp thread (24) of a warp thread pair (23) of binding warp threads (20). Between two adjacent binding points of a warp thread pair (23), the stationary warp thread (25) and the regular warp thread (24) have intersecting points (26).