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.

Shirts are disclosed that may be worn by tactical operators. In an embodiment, the shirt includes a body to be disposed about a torso of a wearer, a body to be disposed about a torso of a wearer, and pair of sleeves to receive the wearer's arms. In addition, the shirt includes a collar assembly including a port including a V-shaped region, and a collar extending from the port. The collar has a first portion extending a first length from the port, and a second portion extending a second length from the port. The first length is longer than the second length, and the second portion extends from the V-shaped region of the port. The body and the collar assembly comprise a first material, the pair of shoulder and the pair of sleeves comprise a second material, and the second material is more abrasion resistant than the first material.

Shirts are disclosed that may be worn by tactical operators. In an embodiment, the shirt includes a body to be disposed about a torso of a wearer, a body to be disposed about a torso of a wearer, and pair of sleeves to receive the wearer's arms. In addition, the shirt includes a collar assembly including a port including a V-shaped region, and a collar extending from the port. The collar has a first portion extending a first length from the port, and a second portion extending a second length from the port. The first length is longer than the second length, and the second portion extends from the V-shaped region of the port. The body and the collar assembly comprise a first material, the pair of shoulder and the pair of sleeves comprise a second material, and the second material is more abrasion resistant than the first material.

The technology described herein relates to vented and insulating garments having an interior garment assembly comprising an interior panel and a middle panel attached at one or more seams defining chambers for retaining thermally-insulating fill material. The seams have a first plurality of openings extending through the interior and middle panels. An exterior garment assembly has a second plurality of openings positioned on the exterior garment assembly such that the second plurality of openings are offset from the first plurality of openings when the exterior garment assembly is worn with the interior garment assembly. The offsetting of the openings may achieve moisture vapor or air transfer from the inside of the garment to the outside environment. The exterior garment assembly and the interior garment assembly may be discrete garment pieces or may be attached at one or more locations.

An absorbent pad for use in a garment is disclosed. The absorbent pad includes a liquid impermeable barrier layer and a functional layer disposed adjacent to the barrier layer, the functional layer having a liquid absorbent component. The absorbent pad also includes a first attaching element coupled to a periphery of the functional layer and a periphery of the barrier layer; and a second attaching element having a first portion and a second portion, wherein the first portion coupled to the first attaching element. The second portion of the second attaching element is arranged to be attached to a fabric body of the garment, thereby attaching the absorbent pad to the garment. The absorbent pad is washable and reusable.

A vapor-permeable insert for item of clothing or accessory, including a collector element adapted to absorb solar radiation, a window element that is transparent to the solar radiation absorbed by the collector element, and an interspace formed between the window element and the collector element, the collector element and the window element being arranged at two opposite faces of the interspace.

A garment having one or more wipe zones for transferring away perspiration from a wearer's skin upon contact with the wearer's skin is provided herein. The wipe zones may be comprised of hydrophobic material formed from yarns having a smaller denier per filament (DPF) than adjacent non-wipe zones on the garment. In some aspects, the DPF of the wipe-zone material is within a range of 0.025 to 0.0025. The wipe zones may be positioned on an outer-facing surface of the garment or an inner-facing surface of the garment in areas that are readily accessible to remove perspiration from the wearer's hands and/or head. Methods of manufacturing a garment having wipe zones are also provided herein.

A garment having one or more wipe zones for transferring away perspiration from a wearer's skin upon contact with the wearer's skin is provided herein. The wipe zones may be comprised of hydrophobic material formed from yarns having a smaller denier per filament (DPF) than adjacent non-wipe zones on the garment. In some aspects, the DPF of the wipe-zone material is within a range of 0.025 to 0.0025. The wipe zones may be positioned on an outer-facing surface of the garment or an inner-facing surface of the garment in areas that are readily accessible to remove perspiration from the wearer's hands and/or head. Methods of manufacturing a garment having wipe zones are also provided herein.

Disclosed and described herein are systems and methods of energy generation from fabric electrochemistry. An electrical cell is created when electrodes (cathodes and anodes) are ‘printed’ on or otherwise embedded into fabrics to generate DC power when moistened by a conductive bodily liquid such as sweat, wound, fluid, etc. The latter acts, in turn, as the cell's electrolyte. A singular piece of fabric can be configured into multiple cells by dividing regions of the fabric with hydrophobic barriers and having at least one anode-cathode set in each region. Flexible inter-connections between the cells can be used to scale the generated power, per the application requirements.

Disclosed and described herein are systems and methods of energy generation from fabric electrochemistry. An electrical cell is created when electrodes (cathodes and anodes) are ‘printed’ on or otherwise embedded into fabrics to generate DC power when moistened by a conductive bodily liquid such as sweat, wound, fluid, etc. The latter acts, in turn, as the cell's electrolyte. A singular piece of fabric can be configured into multiple cells by dividing regions of the fabric with hydrophobic barriers and having at least one anode-cathode set in each region. Flexible inter-connections between the cells can be used to scale the generated power, per the application requirements.