The present disclosure relates to a multiple woven fabric including a ground weave and a pattern weave, in which the ground weave and the pattern weave are arranged to be neighboring, the ground weave includes a plain weave woven so that a warp and a weft participate in weaving, and the pattern weave is a multi-layer weave including a first weave forming a first layer and a second weave separated from the first layer to form a second layer.

An illustrative example method of making an elongated load bearing member includes providing a plurality of tension elements. A plurality of weave fibers are woven together with the tension elements to thereby establish a weave. A traction surface is established on at least one side of the load bearing member. The traction surface is defined by the weave fibers. Coating the weave fibers with a compressible coating provides an exterior surface texture defined at least in part by the weave fibers.

The present disclosure relates to a shoe upper including a stretchable area and a non-stretchable area. The shoe upper is woven by combining a warp yarn and a weft yarn, the weft yarn includes a first weft yarn, which is a stretchable yarn, and a second weft yarn, which is a normal yarn, the first and second weft yarns being alternately arranged next to each other, in the stretchable and the non-stretchable area, the shoe upper is woven with a leno weave and a plain weave in which the first weft yarn and the second weft yarn each are combined to the warp yarn, and the number of weave points of the warp yarn and the second weft yarn is larger in the non-stretchable area than in the stretchable area.

An implantable prosthetic valve that is radially collapsible to a collapsed configuration and radially expandable to an expanded configuration includes an annular frame having an inflow end, an outflow end, and a longitudinal axis. A leaflet structure is positioned within the frame and secured thereto, and a sealing element is secured to the frame. The sealing element includes a first woven portion extending circumferentially around the frame. The first woven portion includes a plurality of interwoven filaments. The sealing element further includes a second woven portion extending circumferentially around the frame and spaced apart from the first woven portion along the longitudinal axis of the frame. At least a portion of the filaments exit the weave of the first woven portion and form loops extending radially outwardly from the frame.

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 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 woven sheet crop material comprising a woven region and a smaller knitted region. The woven region comprises a main body of the material and the knitted region is affixed to the woven region to provide an affixment region for attachment of fixing means, such as C clips or carbine clips.

An exemplary elongated elevator load bearing member includes a plurality of tension elements that extend along a length of the load bearing member. A plurality of weave fibers transverse to the tension elements are woven with the tension elements such that the weave fibers maintain a desired spacing and alignment of the tension elements relative to each other. The weave fibers at least partially cover the tension elements. The weave fibers are exposed and establish an exterior, traction surface of the load bearing member.

This disclosure relates to a light-directing system, comprising a textile sheet material, which can be positioned in a light incidence region in front of a space and has a weft-thread layer composed of a plurality of weft threads, wherein the weft threads are extended substantially linearly and bound mesh openings of the sheet material. According to this disclosure, some or all weft threads have a non-circular thread cross-section bounded by a plurality of individual side parts and are arranged parallel to each other, the orientation of the side parts of the weft threads being uniform.

An illustrative example method of making an elongated load bearing member includes providing a plurality of tension elements. A plurality of weave fibers are woven together with the tension elements to thereby establish a weave. A traction surface is established on at least one side of the load bearing member. The traction surface is defined by the weave fibers. Coating the weave fibers with a compressible coating provides an exterior surface texture defined at least in part by the weave fibers.