A method for forming an anti-counterfeiting feature during knitting of a fabric and a fabric thereof, the fabric is knitted with at least one first yarn, a part of the fabric includes a plurality of featured yarn loops formed by a second yarn, the featured yarn loops constitute an anti-counterfeiting feature, the anti-counterfeiting feature can be directly observed from one side surface of the fabric, the second yarn is formed by twisting at least two sub-yarns with different shades, and shades of the at least two sub-yarns and the first yarn are different from each other, and a shade of the featured yarn loops displayed on the side surface is random. Accordingly, the randomness of yarn twisting makes the anti-counterfeiting feature difficult to be replicated, thereby preventing unscrupulous manufacturers from counterfeiting the fabric.

A method for forming an anti-counterfeiting feature during knitting of a fabric and a fabric thereof, the fabric is knitted with at least one first yarn, a part of the fabric includes a plurality of featured yarn loops formed by a second yarn, the featured yarn loops constitute an anti-counterfeiting feature, the anti-counterfeiting feature can be directly observed from one side surface of the fabric, the second yarn is formed by twisting at least two sub-yarns with different shades, and shades of the at least two sub-yarns and the first yarn are different from each other, and a shade of the featured yarn loops displayed on the side surface is random. Accordingly, the randomness of yarn twisting makes the anti-counterfeiting feature difficult to be replicated, thereby preventing unscrupulous manufacturers from counterfeiting the fabric.

A substrate is mountable on a lacrosse stick head to form a pocket. The head has a throat attached to a shaft, a ball stop attached to the throat, a scoop distal to the throat, and sidewalls extending between the ball stop and the scoop. The substrate includes a top portion and a bottom portion. The top portion is positioned proximate to the scoop and the bottom portion is positioned between the top and the ball stop. The top and bottom portions include yarn knit to form the substrate. A method of making the substrate includes casting the yarn onto a needle, knitting the top and bottom portions, casting the yarn off the needle, tying off the yarn and attaching the substrate to the head.

A substrate is mountable on a lacrosse stick head to form a pocket. The head has a throat attached to a shaft, a ball stop attached to the throat, a scoop distal to the throat, and sidewalls extending between the ball stop and the scoop. The substrate includes a top portion and a bottom portion. The top portion is positioned proximate to the scoop and the bottom portion is positioned between the top and the ball stop. The top and bottom portions include yarn knit to form the substrate. A method of making the substrate includes casting the yarn onto a needle, knitting the top and bottom portions, casting the yarn off the needle, tying off the yarn and attaching the substrate to the head.

A sleeve for protecting an elongate member, including a bus-bar of a battery pack, and method of construction thereof are provided. The sleeve includes a knit wall having a circumferentially continuous outer surface extending along a longitudinal axis between opposite open ends. The knit wall is formed at least in part by multifilament flame-resistant yarn. The multifilament flame-resistant yarn is knit to form both the knit wall, and also first ribs extending lengthwise along the circumferentially continuous outer surface or second ribs extending annularly about said circumferentially continuous outer surface. An impervious, flame-resistant coating is bonded to an outer surface of the circumferentially continuous knit wall.

A method for manufacturing a cut resistant fabric includes: supplying a polyethene yarn with a thickness of 50-225 dtex as a protective yarn through a first yarn carrier of a circular knitting machine to a feeder needle at a first selected tension; supplying simultaneously an uncoated elastane yarn with a thickness of 20-80 dtex as a first additional yarn through a second yarn carrier of the circular knitting machine to the same feeder needle at a second selected tension that is higher than the first selected tension of the protective yarn; forming a fabric from the protective yarn and the first additional yarn as single-jersey knits; and interlocking the protective yarn and the first additional yarn in each single-jersey knit of the fabric using a heat treatment step on a stenter frame.

A method for manufacturing a cut resistant fabric includes: supplying a polyethene yarn with a thickness of 50-225 dtex as a protective yarn through a first yarn carrier of a circular knitting machine to a feeder needle at a first selected tension; supplying simultaneously an uncoated elastane yarn with a thickness of 20-80 dtex as a first additional yarn through a second yarn carrier of the circular knitting machine to the same feeder needle at a second selected tension that is higher than the first selected tension of the protective yarn; forming a fabric from the protective yarn and the first additional yarn as single-jersey knits; and interlocking the protective yarn and the first additional yarn in each single-jersey knit of the fabric using a heat treatment step on a stenter frame.

The application relates to a fire-resistant textile composite having an upper surface and a lower surface. The composite contains a nonwoven layer and a knit layer. The nonwoven layer has a first and second side and contains a nonwoven textile. The nonwoven textile contains a plurality of first fire-resistant fibers, where the first fire-resistant fibers are non-thermoplastic. The nonwoven layer forms the lower surface of the textile composite. The knit layer contains a knit textile having a first and second side and the second side of the knit layer is adjacent to the first side of the nonwoven layer. The knit textile contains a plurality of second fire-resistant yarns, where the second fire-resistant yarns are non-thermoplastic. At least a portion of the first fire-resistant fibers from the nonwoven layer extend through the first side of the knit layer and form the upper surface of the textile composite.

Stapling assemblies for use with a surgical stapler are provided. In one exemplary embodiment, a stapling assembly can include a cartridge and a knitted adjunct that is configured to be releasably retained on the cartridge. The adjunct can have a tissue-contacting layer formed of at least first fibers, a cartridge-contacting layer formed of at least second fibers, spacer fibers intertwined with and extending between the tissue-contacting layer and the cartridge-contacting layer to thereby connect the tissue-contacting and cartridge-contacting layers together, and at least one fiber interconnecting at least a portion of a terminal edge of each of the tissue-contacting and cartridge-contacting layers to form a finished edge that substantially prevents fraying thereof.

Embodiments of the disclosure provide structures for sensing, activation, and signal networking in a composite textile. According to one embodiment, a composite textile can comprise an activation layer of a reactive yarn knit into a fabric. The reactive yarn can have at least one physical property that changes in response to a stimulus. A signaling layer of a first conductive yarn can be knit into the fabric with the activation layer. The first conductive yarn provides the stimulus to the reactive yarn. A sensing layer comprising second conductive yarn can be knit into the fabric with the activation layer and signaling layer. The second conductive yarn can provide a feedback signal corresponding to the stimulus provided by the first conductive yarn of the signaling layer.