An assembly is described for chairs, armchairs, sofas and the like, comprising a knitted artefact (1) and sliders (12). The artefact (1) comprises a multilayer and two ends (11) of tubular shape for fixing the multilayer, wherein the multilayer comprises a knitted fabric front layer (2) and a knitted fabric rear layer (3) fixed to sliders (12) of the artefact (1) at said two ends (11). The artefact (1) further comprises heat-shrinking yarns (5) associated with the multilayer, wherein the heat-shrinking yarns (5) are fixed with a series of connection points (7) spaced apart to the sliders (12) so as to develop in weft between the two ends (11) of the artefact (1).

In one aspect, the present disclosure provides knitted component comprising with a first surface and a second surface, the first surface facing opposite the second surface. A pod may have the first surface and the second surface, and an edge region may have the first surface and the second surface, where the edge region at least partially demarcates the pod. A first yarn may substantially form the first surface of the pod, where the first yarn is a fusible yarn. A second yarn may substantially form the second surface of the pod, and the second yarn may substantially form the first surface of the edge region.

Embodiments of the invention disclosed herein are directed to articles of clothing that allow for monitoring of different analytes (e.g., electrolytes and molecules) in human sweat during fitness activity, while training, or simply in everyday life. The clothing includes a sensor system completely integrated in textile such that every sensing part is made of textile fibers. The clothing is able to control, collect, analyze, and expel the sweat over time. The textile sensor allows a spontaneous absorption of body sweat directly from the skin, while it is produced, using the hydrophilic natural properties of the textile. Then, once adsorbed, the flux of sweat is controlled and guided through the textile using a gradient of the textile's hydrophilic properties. The sweat guided through the textile is analyzed through an electrochemical sensor woven into the textile. Finally, the sweat is collected in a reservoir and expelled for evaporation.

A double-faced fabric of knitted construction has a first layer and a second layer. The first layer forms a first out-ward-facing surface of the fabric, which includes a first yarn that includes first inherently fire-resistant fibers and optionally first elastane fibers. The second layer forms a second outward-facing surface of the fabric, which includes a second yarn that includes second FR viscose fibers and optionally second elastane fibers, other cellulosic-derived fiber, synthetic fire-resistant fiber, antibacterial fiber or combination of such. The first layer and the second layer are attached to each other by interlocking relationship between the first yarn and the second yarn. The first outward-facing surface and the second outward-facing surface of the fabric may used for a garment's outer surface and the inner surface, respectively.

A method may include one or more of the following steps: knitting a first knit layer and a second knit layer on a knitting machine, where the first knit layer and the second knit layer each include a plurality of intermeshed loops, and where at least one loop of the first knit layer is intermeshed with at least one loop of the second knit layer; inlaying an inlaid strand between the first knit layer and the second knit layer during the knitting of the first knit layer and the second knit layer, where the inlaid strand includes a thermoplastic material having a melting point; and applying heat to at least a portion of the thermoplastic material of the inlaid strand such that the portion of the thermoplastic material rises to a temperature at or above the melting point.

A double layer knitted element includes a first layer comprising a first yarn, a second layer comprising a second yarn, and a third yarn arranged at least in part between the first and second layer. The third yarn is attached to at least one of the first layer and the second layer by a plurality of tuck stitches, wherein there is at least one miss stitch between two successive tuck stitches of the third yarn.

A semi-finished component for the manufacture of knitted uppers, comprising a plain knitting and a purl knitting, and at least one longitudinally extended channel which is formed within the knitting between the plane formed by the plain knitting and the plane formed by the purl knitting, the at least one longitudinally extended channel being engageable by an elongated engagement element which forms a lace or a reinforcement element designed to engage with a lace.

Methods of manufacture, including exposing the upper to steam while in a tensioned state to at least partially melt the fusible yarn to adjacent yarns is described. Subsequent cooling of the fusible yarn retains the upper in a stretched condition.

Knitted components may include a first knit layer including a first yarn, a second knit layer, and a plurality of inlaid courses of a high tenacity yarn having a tenacity of at least six grams-force per denier. The plurality of inlaid courses of the high tenacity yarn may include at least three courses of high tenacity yarn, each of which may be separated from an adjacent course of the first plurality of courses of the high tenacity yarn by no more than five courses of the first yarn.

A knitted component may include a knit element formed with a plurality of courses and a plurality of wales, where the plurality of courses include a first course and the plurality of wales include a first wale and a second wale. A set of inlaid strands including at least a first inlaid strand and a second inlaid strand may be included. A first area and a second area may be included, where in the first area, each inlaid strand of the set of inlaid strands extends through at least a portion of the first course, and where in the second area, the first inlaid strand extends through the first wale and the second inlaid strand extends through the second wale.