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.

Some embodiments provide a protective motorcycle blazer for protecting a motorcyclist. The protective motorcycle blazer includes an outer layer comprising textile fabric for providing an appearance of a blazer, a middle layer comprising abrasion resistant material for providing abrasion resistance to the protective motorcycle blazer, and an inner layer for providing an interface between the motorcyclist and the protective motorcycle blazer.

Aspects herein are directed to an apparel layer system configured to provide variable levels of insulation, warming, or air permeability. The apparel layer system comprises a first layer of material and a second layer of material both extending in a first planar direction. A third layer of material is positioned between the first and the second layers of material and is selectively affixed thereto. An adjustment mechanism coupled to the second layer of material can be mechanically manipulated to shift the second layer of material between different positions or states to achieve variable levels of offset between the first and second layers of material in the first planar direction and in a second direction perpendicular to the first planar direction.

Aspects herein are directed to an apparel layer system configured to provide variable levels of insulation, warming, or air permeability. The apparel layer system comprises a first layer of material and a second layer of material both extending in a first planar direction. A third layer of material is positioned between the first and the second layers of material and is selectively affixed thereto. An adjustment mechanism coupled to the second layer of material can be mechanically manipulated to shift the second layer of material between different positions or states to achieve variable levels of offset between the first and second layers of material in the first planar direction and in a second direction perpendicular to the first planar direction.

Aspects herein are directed to an article of apparel having a vent opening formed by overlapping the edges of a first panel and a second panel. A plurality of discrete overlay film structures are applied to the second panel adjacent to the vent opening. When the article of apparel is exposed to an external stimulus, the film structures undergo a reversible increase in dimension in at least the z-direction which cause the second panel of material to undergo a reversible decrease in dimension in the direction of a longitudinal axis of the vent opening thereby causing the vent opening to dynamically transition from a closed state to an open state.

Aspects herein are directed to an article of apparel having a vent opening formed by overlapping the edges of a first panel and a second panel. A plurality of discrete overlay film structures are applied to the second panel adjacent to the vent opening. When the article of apparel is exposed to an external stimulus, the film structures undergo a reversible increase in dimension in at least the z-direction which cause the second panel of material to undergo a reversible decrease in dimension in the direction of a longitudinal axis of the vent opening thereby causing the vent opening to dynamically transition from a closed state to an open state.

A garment body of a fan-equipped garment includes: an outer cloth in which a fan mount part is formed, the fan mount part being configured to receive a fan; and an inner cloth disposed closer to a wearer than the outer cloth. An air-through part is formed only at a hem part of the garment body, the air-through part connecting a space between the outer cloth and the inner cloth and a space at an inner surface side of the inner cloth.

A garment body of a fan-equipped garment includes: an outer cloth in which a fan mount part is formed, the fan mount part being configured to receive a fan; and an inner cloth disposed closer to a wearer than the outer cloth. An air-through part is formed only at a hem part of the garment body, the air-through part connecting a space between the outer cloth and the inner cloth and a space at an inner surface side of the inner cloth.

A protective garment comprises a thermal liner, a moisture barrier, and an outer shell. The protective garment includes one or more transferal portions located at predetermined areas to enhance evaporative heat transfer. In some embodiments, the transferal portions of the protective garment have Resistance to Evaporation of a Textile (Ret) of less than 20 m2 Pa/W.

A protective garment comprises a thermal liner, a moisture barrier, and an outer shell. The protective garment includes one or more transferal portions located at predetermined areas to enhance evaporative heat transfer. In some embodiments, the transferal portions of the protective garment have Resistance to Evaporation of a Textile (Ret) of less than 20 m2 Pa/W.