An adaptive material garment system includes a number of components to effectively transport and exhaust moisture and thermal energy while protecting the wearer from undesired levels of air permeability. Therefore, an adaptive material responsive to stimuli, such as moisture, is used as a base layer against a wearer's skin. The base layer is effective to transport thermal energy and/or sweat away from the skin. The base layer may be formed with a first gauge greater than and a denier that is less than an outer article. The outer article may also be formed from an adaptive material responsive to the same or different stimuli. The outer article may also have a wind-resistant panel having apertures and a selectively coupled perimeter.

The present invention is directed toward an article of apparel effective to regulate the temperature of the wearer. In an embodiment, the article of apparel includes a base textile with a thermal regulation membrane. The thermal regulation membrane contains a plurality of system-reactive components selectively engaged heat and/or moisture. In an embodiment, the printed coating includes a cooling agent, a phase change material, and a heat dissipation material. In operation, the article of apparel is effective to delay/diminish the rise in skin temperature (compared to a garment lacking the membrane), increasing wearer comfort.

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.

The technology described herein relates to breathable, vented, and insulating garments. More particularly, the technology described herein relates to garments with chambers to retain an insulating fill material. Openings along seams between the insulating chambers may achieve evaporative moisture or air transfer from the inside (proximal to the body of a wearer) of the garment to the outside environment. In an aspect, the garments comprise one or more insulated zones provided with one or more vented-insulation sections provided at locations on the garment configured to align with one or more areas of a wearer's body that are more sensitive to environmental conditions (e.g. temperature) and/or are prone to faster heat loss.

A neck gaiter comprising a knit body having a densely knit portion, a loosely knit portion, and a seamless transition from the densely knit portion to the loosely knit portion. A method of manufacturing a neck gaiter that includes knitting a knit body having a densely knit portion that seamlessly transitions into a loosely knit portion to form a breathable region.

Aspects herein relate to apparel items and apparel systems that utilize applied or printed foam nodes to provide, among other things, stand-off between an apparel item and a wearer's skin surface. One or more of the foam nodes, or areas of the textile surrounding the foam nodes, may be perforated to provide a fluid communication path between an inner-facing surface and an outer-facing surface of the apparel item. The communication path may be used to facilitate air exchange between the external environment and the wearer's body and/or to provide an exit path for moisture vapor generated by the wearer.

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 composite cloth includes a fabric sheet and at least one functional film. The fabric sheet defines multiple micropores extending therethrough. The functional film is bonded to a first surface of the fabric sheet, and includes a fabric sheet-binding portion which is bonded to and conforms with the first surface of the fabric sheet, and multiple protrusion-forming portions which are connected to the fabric sheet-binding portion and which define multiple vacuum-molded protrusions extending into corresponding ones of the micropores. Each of the vacuum-molded protrusions has an open end defining an opening which extends through the fabric sheet such that each of the vacuum-molded protrusions is in spatial communication with a corresponding one of the micropores.

The invention provides a process for manufacturing a dynamically warm-keeping garment with a one-way moisture transferring function. The warm-keeping garment is made of a one-way moisture transferring fabric that includes a surface layer, a warm-keeping layer and a lining layer or includes the surface layer, a first warm-keeping layer, an intermediate interlayer, a second warm-keeping layer and the lining layer. The above technical solution addresses the following problems of traditional warm-keeping cotton clothes and down jackets: temperature loss caused by unsmooth sweat discharge; complex and difficult processing due to underarm zippers for ventilation; static damage and possible explosion of washing machines by air pressure due to air tightness during washing.

A splash resistant multi-layered structure is provided. The structure includes a specific arrangement of layers of material and a plurality of three-dimensional spacers that helps prevent penetration through the structure by a fluid that contacts an outer surface of the structure due to a state of forced separation that exists between two adjacent layers of the structure due to the presence of the plurality of three-dimensional spacers positioned between the layers. The plurality of three-dimensional spacers can be positioned on one of the adjacent layers of the structure such that a distance at least as large as the maximum height of the plurality of three-dimensional spacers separates the two layers from each other and can be present on a layer of material in a continuous or discontinuous pattern or can be present on a layer of material in a random fashion. The presence of the three-dimensional spacers can reduce the basis weight or eliminate one or more layers of the structure, which, in turn, can reduce thermal resistance, lower the pressure drop across the layers of the structure, and reduce the overall weight of the structure to enhance breathability and comfort.