A protective garment is constructed with a fibrous material. The fibrous material comprises a first nonwoven layer, a second nonwoven layer, and a nanofiber layer laminated between the first nonwoven layer and the second nonwoven layer. The fibrous material has a mean flow pore size greater than or equal to about 0.02 micron and less than or equal to about 0.5 microns, and a water vapor transmission rate greater than or equal to about 10000 g/m.sup.2/day and less than or equal to about 100000 g/m.sup.2/day. In a method of making a fibrous layer, a first nonwoven layer and a nanofiber layer are provided. A polyurethane reactive resin is applied to the first nonwoven layer in an amount of 2 to 30 g/m.sup.2. The nanofiber layer is then laminated to the first nonwoven layer applied with the polyurethane reactive resin and pressed to form the fibrous layer.

Aspects herein are directed to a vented upper-body garment that includes a plurality of panels that extend across a back aspect of a torso region of the garment, around first and second sides of the torso region, and at least partially across a front aspect of the torso region. Respective edges of the panels overlap each other to form vent openings that facilitate the flow of air into and out of the garment.

A breathable, high-visibility garment comprising discrete islands of unsupported, retroreflective laminate.

The present invention concerns an article of apparel including: a first woven area, where the first woven area includes a first weaving density and a first yarn weight per unit length; a second woven area arranged adjacent to the first woven area, where the second woven area includes a second weaving density and a second yarn weight per unit length; and a third woven area arranged adjacent to the second woven area, where the third woven area includes a third weaving density and a third yarn weight per unit length. The second weaving density in the second woven area changes gradually from the first weaving density to the third weaving density and/or the second yarn weight per unit length in the second woven area changes gradually from the first yarn weight per unit length to the third yarn weight per unit length.

The present invention concerns an article of apparel including: a first woven area, where the first woven area includes a first weaving density and a first yarn weight per unit length; a second woven area arranged adjacent to the first woven area, where the second woven area includes a second weaving density and a second yarn weight per unit length; and a third woven area arranged adjacent to the second woven area, where the third woven area includes a third weaving density and a third yarn weight per unit length. The second weaving density in the second woven area changes gradually from the first weaving density to the third weaving density and/or the second yarn weight per unit length in the second woven area changes gradually from the first yarn weight per unit length to the third yarn weight per unit length.

Articles and methods of using and making adaptive garment portions are provided. An adaptive garment portion is one that has shifting surfaces with apertures that shift from an aligned to an offset orientation depending on environmental conditions/stimuli. For example, a first surface material and a second surface material may be coupled by a responsive material portion. The responsive material portion may physically change in response to a change in environmental conditions internal or external to the garment (e.g., thermal energy, moisture) and/or stimuli (e.g., light energy, electrical energy, magnetic fields). The physical change in the responsive material portion facilitates the planar shift of the first surface material relative to the second surface material.

A method of integrating a hair extension weft on a human scalp is disclosed. The hair extension weft includes a polyurethane strip enclosing a plurality of meshes arranged in a longitudinal direction of the strip. Each mesh is configured to have a plurality of contiguous hairs attached in a transverse orientation. The hair extension weft includes several gaps formed between the plurality of meshes in the longitudinal direction. Each gap is configured to receive a plurality of hairs from the human scalp. Upon clipping the hair extension weft to the human scalp, the plurality of hairs is pulled through each gap with a needle shaped tool placed under the each gap of the hair extension weft. A microbead is clamped to the plurality of hairs pulled through the each gap, to anchor the hair extension weft to the human scalp.

A garment has excellent contact cold sensation and gives persistent contact cold sensation but also can reduce heatful feeling and is suitably wearable in wearing scenes such as offices and homes. The garment includes one or plural fans for taking external air into a space between the garment and the body. A fabric of the garment has a contact cold/warm sensation value Q-max of 0.30 W/cm.sup.2 or larger and a basis weight of 250 g/m.sup.2 or less.

A garment has excellent contact cold sensation and gives persistent contact cold sensation but also can reduce heatful feeling and is suitably wearable in wearing scenes such as offices and homes. The garment includes one or plural fans for taking external air into a space between the garment and the body. A fabric of the garment has a contact cold/warm sensation value Q-max of 0.30 W/cm.sup.2 or larger and a basis weight of 250 g/m.sup.2 or less.

Aspects herein are directed to an apparel item that promotes thermo-regulation through the use of engineered openings, venting, and/or stand-off structures. In exemplary aspects, 20-45% of the apparel item may comprise the engineered openings. Vents may be positioned on the apparel item in areas that experience high amounts of air flow to help channel air into the apparel item. The stand-off structures may be positioned on an inner-facing surface of the apparel item where they help to create a space between the apparel item and the wearer's body surface in which air can flow and help cool the wearer by promoting evaporative cooling.