A woven textile includes, in at least one of the warp or weft directions, non-flocked yarns and flocked yarns. The flocked yarns include a support yarn having a core covered with an adhesive layer. The support yarn has a base diameter. Protruding filaments provide the flocked yarns with an apparent diameter. The non-flocked yarns have a diameter which is smaller than the apparent diameter and larger than the base diameter of the flocked yarns.

A deformation detecting device includes weft yarns and warp yarns woven together. At least some of the weft yarns, or some weft yarns, and some warp yarns, are electrically conductive. The weft yarns include a flocking made up of non-electrically conductive fibers protruding substantially radially from the weft yarns. The electrically conductive yarns are connected to conductive ends for applying an electrical voltage, such that yarns that are connected to conductive ends with different polarities define respective plates of a capacitive sensor, while the fibers of the flocking of the weft yarns define a dielectric material interposed between the capacitive sensor plates. The device comprises an electronic control and processing unit configured to detect a deformation of the fabric based on a capacitance variation of the capacitive sensor.

A woven textile includes, in at least one of the warp or weft directions, non-flocked yarns and flocked yarns. The flocked yarns include a support yarn having a core covered with an adhesive layer. The support yarn has a base diameter. Protruding filaments provide the flocked yarns with an apparent diameter. The non-flocked yarns have a diameter which is smaller than the apparent diameter and larger than the base diameter of the flocked yarns.

A deformation detecting device includes weft yarns and warp yarns woven together. At least some of the weft yarns, or some weft yarns, and some warp yarns, are electrically conductive. The weft yarns include a flocking made up of non-electrically conductive fibers protruding substantially radially from the weft yarns. The electrically conductive yarns are connected to conductive ends for applying an electrical voltage, such that yarns that are connected to conductive ends with different polarities define respective plates of a capacitive sensor, while the fibers of the flocking of the weft yarns define a dielectric material interposed between the capacitive sensor plates. The device comprises an electronic control and processing unit configured to detect a deformation of the fabric based on a capacitance variation of the capacitive sensor.

A method for enriching a textile fiber bundle for a weaving machine involves moving a textile fiber bundle along a bundle running direction, providing a first electrospinning station for producing solid nanofibers by an electrospinning device, depositing, the solid fibers on the textile fiber bundle to obtain an enriched textile fiber bundle, and moving the enriched textile fiber bundle towards a work station. An electrospinning station for enriching a textile fiber bundle has an electrospinning device having a reserve for containing an electrospinnable enrichment solution, an emitter electrode, and a collector electrode, facing and spaced apart from the emitter electrode, so that, by effect of a generated electric field, formation and transport of solid nanofibers on the textile fiber bundle take place. A yarn is composed of an enriched textile fiber bundle having textile fibers enriched with solid nanofibers obtained by electrospinning and interwoven with the textile fibers.