A woven textile structure is formed by weaving a first woven layer including first yarns and weaving a second woven layer including first yarns, where the woven layers are arranged in a stacked manner and are separated from each other. During the weaving of the first and second woven layers, second yarns are inserted along an intermediate span in the weft direction of the woven textile structure, where the second yarns are elongated to an elongated length during the insertion in the weft direction. First yarns of the first woven layer are interlaced with first yarns of the second woven layer and a second yarn of the intermediate span at a plurality of interlacing locations along the woven textile structure so as to define stitches at each interlacing location, where each stitch joins the first woven layer with the second woven layer.

An article of footwear may include an upper incorporating a knitted component. An inlaid strand extends through the knitted component. A combination feeder may be utilized to inlay the strand within the knitted component. As an example, the combination feeder may include a feeder arm that reciprocates between a retracted position and an extended position. In manufacturing the knitted component, the feeder inlays the strand when the feeder arm is in the extended position, and the strand is absent from the knitted component when the feeder arm is in the retracted position.

In one aspect, a textile component including bulking yarn is disclosed. In embodiments, the textile component is a knitted component. In one embodiment, an article of footwear includes a knitted component arch support configured to reduce the rate of pronation. A support structure may include a fusible yarn adjacent to an external surface of the arch support, a bulking yarn, and a nonfusible yarn. In certain embodiments, an arch support includes compartments and flex lines. In another aspect, an article having a knitted component includes a rigid material, a bulking yarn, and a flexible material. The rigid material may be fusible yarn. Methods for forming a textile component are provided. One embodiment involves knitting a first section comprising a fusible yarn, a second section comprising a bulking yarn, and a third section comprising a nonfusible yarn, and heating.

A method for providing intermediate manufactures for production of manufactures such as an inshoe, footlet, no-show sock, shoes or the like with double thickness, with a circular hosiery knitting machine and an intermediate manufacture obtained with the method. The method has the particularity that it comprises at least the following steps: a step of providing a first tubular portion of knitted fabric; a casting-off step, in which a portion of knitted fabric is provided by moving to knit a group of contiguous needles at the at least one feed; a casting-on step, in which a portion of knitted fabric is provided by moving to knit a group of contiguous needles at the at least one feed; a step of providing a second tubular portion of knitted fabric by actuating the needle cylinder with a continuous rotary motion about its own axis in one direction of rotation.

A knit component may include a knit-in tensile area, which may include an opening at least partially bounded by a first intersecting portion and a second intersecting portion. A course of tensile material that is integrally knitted with the first intersecting portion via a knit stitch may include a float extending from the first intersecting portion, across the opening, to the second intersecting portion. A knitting method may knit courses of the knit component on needle beds and then widen and/or narrow parts of the opening by transferring stitches of one of the courses of the knit component to different needles.

A knitted component may include a knit element with a first surface and an opposite second surface. An inlaid yarn may extend through the knit element and between the first surface and the second surface. A secured area where the first surface and the second surface are secured together may be included, where the inlaid yarn is secured by loops forming the first surface and the second surface. A cushioning area may be included, where the cushioning area has a tubular construction such that the first surface and the second surface are separable, forming a cavity therebetween, and where the inlaid yarn extends through the cavity formed between the first surface and the second surface.

A process for manufacturing a tubular knitted item (1) with intarsia design, comprising the steps of: programming a circular weft knitting machine for intarsia design by defining a tubular intarsia knitted item (1) to be manufactured, extending longitudinally between a first end (2) and a second end (3) and consisting of a plurality of knitted courses following one another;
wherein the programming step comprises the steps of: defining a turning position (4), which divides the tubular item into a first fabric (5) and a second fabric (6), wherein the tubular item is configured for being manipulated so as to be at least partially turned over itself, by folding it in the turning position so that the second fabric overlaps the first fabric in order to obtain a double fabric item; defining at least one first area (10) of the first fabric, delimited by a needle section and by a number of successive courses of the area, and having a desired shape; defining at least one first counter-area (20) of the second fabric, delimited by a needle section and by a number of successive courses of the area, in which the first counter-area has a respective shape; producing intarsia knitted fabric so as to manufacture the tubular knitted item according to the programming step; wherein the first area (10) is manufactured according to a first knitted structure and the first counter-area (20) is manufactured according to a second knitted structure.

Disclosed is a shoe upper with an illuminating logo. The upper includes a main body part, a logo part, and a lighting unit, in which the logo part for illumination may be formed integrally with the upper, providing the upper with an illumination feature. In this way, the upper with an illuminating logo can be manufactured with a reduced amount of time, leading to an improved manufacturing efficiency. In addition, the logo part is much less likely to come off and there is no need for an adhesive or bonding, creating an aesthetically attractive appearance from outside.

A knitted component with a surface that includes first areas and second areas having different relative coefficient of frictions and that are formed in an alternating pattern. The first areas of the first surface are 40% to 80% of the total surface area for the first surface. The alternating pattern may be in the form of concentric shapes. The alternating pattern may have linear boundaries and curvilinear boundaries between first areas and second areas. The first areas can be formed from a first yarn having a core and a coating. The coating at least partially surrounds the core.

Advances in actuating fabrics could enable a paradigm shift in the field of smart wearables by dynamically fitting themselves to the unique topography of the human body. Active fabrics and fitting mechanisms are described herein that enable garments to conform around surface concavities without requiring high elasticity or a multiplicity of closure devices. Advanced materials and systems innovations (1) enable novel garment manufacturing and application strategies, (2) facilitate topographical fitting (spatial actuation) through garment architectural design, and (3) provide tunable NiTi-based SMA actuation temperatures to enable actuation on the surface of human skin. Such fabrics and garments are usable in a variety of fields including medical compression, technical sportswear, exosuits, space suits and components thereof, or non-garment applications.