A facemask having a graphene layer providing antibacterial and antiviral properties. The facemask is also able to generate electricity from the wearer's breath. The graphene is a three dimensional graphene produced in situ the facemask by burning a suitable material in the facemask with a laser, i.e. laser induced graphene (LIG). Typically, the graphene comprises hydrophilic graphene, in such a way that the graphene is more hydrophilic towards one side of the substrate and less hydrophilic towards the other side of the substrate, which provides the possibility of generating an electrical potential difference using human breath.

Provided are a cloth and a protective product, which allow for any color appearance and have excellent protection performance against electric arcs. The cloth has a woven fabric structure, wherein a front-surface spun yarn containing an infrared absorber- and/or electrically conductive agent-containing fiber and not containing carbon is located on a front surface, while a back-surface spun yarn containing a carbon-containing fiber is located on a back surface, and the cloth has an ATPV value of 8.0 cal/cm.sup.2 or more in Arc Resistance Test ASTM F1959-1999.

A lower body outer garment, such as a pant or legging, is provided which has a construction and hidden support which helps to redefine the wearer's appearance. The support is in one embodiment provided in the form of internal mesh re-enforcing panels that lift the buttocks and flatten the tummy. The invention also relates to twill or denim fabric versions of the lower garment, and includes the front and rear power control panels having strategic hem placement to avoid cutting into fleshy areas on the wearer or to lift and sculpt both the front and backside of the wearer.

A yarn or thread may include a plurality of substantially aligned filaments, with at least ninety-five percent of a material of the filaments being a thermoplastic polymer material. Various woven textiles and knitted textiles may be formed from the yarn or thread. The woven textiles or knitted textiles may be thermal bonded to other elements to form seams. A strand that is at least partially formed from a thermoplastic polymer material may extend through the seam, and the strand may be thermal bonded at the seam. The woven textiles or knitted textiles may be shaped or molded, incorporated into products, and recycled to form other products.

A construction for a glove or other article of clothing for use in hazardous environments is disclosed, comprising a first layer comprising a laminate that includes an inner layer comprising a woven, nonwoven, or knit material, an intermediate layer comprising a barrier to the passage therethrough of liquids that overlies the inner layer, and a thermal layer affixed to and overlying the intermediate layer in at least a portion of a bridge area. The thermal layer is approximately 0.30 mm thick. The construction also includes a second layer attached to and overlying the first layer to form an outer portion for the glove or other article of clothing. The first layer and the second layer combined provides a thermal protection performance (TPP) of at least approximately 75% greater than a reference combination of the first and the second layer that does not include the thermal layer.

A system automatically generates apparel collection imagery from user-provided imagery. The user-provided imagery includes images of people wearing one or more garments. The system uses segmenting analysis to analyze the user-provided image to identify locations of the garment. From the locations of the garments, the system can determine which garments from an apparel collection can be used to replace those in the user-provided imagery. The system uses pose estimation on the user-provided imagery and modifies a preview image of a replacement garment from the collection. This modified replacement garment image is used to replace the garment in the user-provided imagery.

Cleansing devices in the form of ergonomic scrub gloves for cleansing various surfaces including large animals and associated animal contact surfaces. The gloves include an inner layer, which is generally waterproof, with an outer layer comprising an abrasive weave.

In one aspect, a method of manufacturing a protective textile may include steps of (a) twisting a first yarn with a tungsten filament; and (b) using a second yarn to cover the yarn-tungsten product generated in step (a). The yarn generated in step (b) is further twisted with an elastic spandex. In one embodiment, the first yarn is selected from a group of Nylon, Polyethylene Terephthalate (PET), cotton yarn, bamboo fiber and Tencel. In another embodiment, a Polyethylene (PE) fiber is the second yarn, and the third yarn may include Nylon, PET or PE. The protective textile is advantageous because it is light, thin, soft and highly cut resistant. Also, it has great electrical conductivity and chemical stability, and it is not easy to deform after washing.

Protective combat clothing (PCC) may include a shirt and trousers, wherein the shirt and the trousers are at least partially made of woven fabric made of a composition of the materials comprising flame-resistant fiber, flame-resistant meta-aramid fiber, heat-resistant fiber, polyimide and anti-static fiber.

A therapeutic apparel article is configured with a supple wearable fabric article that can be configured over limb or nub of an amputated limb. The therapeutic apparel article is configured with a plurality of nodes for detachably attaching vibrating devices thereto. In addition, a control unit having a power source may be detachably attached to the wearable fabric article. A conductive network may extend from the control unit and/or the power source to provide electrical power to the nodes and the vibrating devices attached. A user may attach vibrating devices to various nodes of the wearable fabric article as desired. In addition, the vibrating devices and the control unit can be detached from the wearable fabric article to enable the wearable fabric article to be washed.