A three-dimensional knitted fabric with a large-diameter circular knitting machine is knitted with a plurality of stitches that form a plurality of stitch courses oriented in each case in a stitch-course direction of the knitted fabric and a plurality of stitch wales oriented in each case in a stitch-wale direction of the knitted fabric, wherein at least one of the stitches is in the form of at least one corrugation-forming stitch, which extends in the stitch-wale direction over a plurality of stitch courses and binds at least one corrugation in the knitted fabric.

A spunbond nonwoven fabric. The fabric has a first surface and a second surface and a visually discernible of three-dimensional features on one of the first and second surface, each of the three-dimensional features defining a microzone. Each microzone has a first region and a second region, the first and second regions having a difference in values for an intensive property. Fibers of the spunbond nonwoven fabric are thermally bonded at the second regions. The second regions are fluid permeable. The fibers of the spunbond nonwoven fabric are thermally bonded with point bonds within an area selected from the first regions, the second regions, or a combination thereof

A knitted component may include a course of a first yarn type and a course of a second yarn type, a first surface at least partially formed by the course of the first yarn type, and a cavity formed within the knitted component that is recessed relative to the first surface. A first float formed by the course of the second yarn type may extend across the cavity and may be exposed, and the course of the second yarn type may include a stitch that is knitted into the knitted component adjacent the float.

A knitted component may include a loft zone having at least one first loft portion that is integrally knit. The loft portion may include a first knitted layer having an elasticated first material, a second knitted layer, a void between the first knitted layer and the second knitted layer, and at least one course of a second material that is knitted within the void and causes the second knitted layer to extend away from the first knitted layer by a first distance. The at least one course of the second material may include at least one float and may project into the void. The second material may have a greater resistance to bending than the elasticated first material.

A bag assembly has a primary storage chamber and a carrying structure, and the carrying structure having a panel and a shoulder strap extending from the panel. The strap and the panel are seamlessly integrated. The primary storage chamber is a first three dimensional (3D) knit structure having a first material or combination of materials and the carrying structure is a second 3D knit structure having a second material or combination of materials. The primary storage chamber is fixed to the panel of the carrying structure to form the bag assembly. Also provided is a bag assembly in which the primary storage chamber is a first 3D knit structure having a first knit pattern and the carrying structure is a second 3D knit structure having a second knit pattern. Also provided is a method for customizing locations of 3D knit features based on user dimensions.

A spunbond nonwoven fabric. The fabric has a first surface and a second surface and at least a first and second visually discernible zone on at least one of the first and second surface, each of the first and second zones having a pattern of three-dimensional features, each of the three-dimensional features defining a microzone. Each microzone has a first region and a second region, the first and second regions having a difference in values for an intensive property, and wherein the difference in values for an intensive property for at least one of the microzones in the first zone is different from the difference in values for the intensive property for at least one of the microzones in the second zone.

A knitted component may include a course of a first yarn type and a course of a second yarn type, a first surface at least partially formed by the course of the first yarn type, and a cavity formed within the knitted component that is recessed relative to the first surface. A first float formed by the course of the second yarn type may extend across the cavity and may be exposed, and the course of the second yarn type may include a stitch that is knitted into the knitted component adjacent the float.

A method for making a prosthetic liner includes the steps of providing a textile sleeve, applying an uncured silicone material onto an inner surface of the textile sleeve and impregnating interstices of a high-density knit structure of the textile sleeve. The silicone material is a fast-cure silicone material arranged to reach at least 90% cross-linking faster than conventional silicone material. The silicone material is preferably limited to the inner surface of the textile sleeve, whereas the outer surface is devoid of the silicone material. The silicone defines an inner layer forming the interior surface of the liner, and the outer surface of the textile sleeve forms the exterior surface of the liner. A thickness of the liner from the interior surface of the liner to the inner surface of textile layer consists of the silicone of the inner layer.

A bag assembly has a primary storage chamber and a carrying structure, and the carrying structure having a panel and a shoulder strap extending from the panel. The strap and the panel are seamlessly integrated. The primary storage chamber is a first three dimensional (3D) knit structure having a first material or combination of materials and the carrying structure is a second 3D knit structure having a second material or combination of materials. The primary storage chamber is fixed to the panel of the carrying structure to form the bag assembly. Also provided is a bag assembly in which the primary storage chamber is a first 3D knit structure having a first knit pattern and the carrying structure is a second 3D knit structure having a second knit pattern. Also provided is a method for customizing locations of 3D knit features based on user dimensions.

The invention provides bras having enhanced dynamic performance and comfort as well as a method of manufacture thereof. Two-dimensional knitting is utilized to generate three-dimensional structures in the bra that conform to unique three-dimensional shapes of the wearer.