Described herein are shields adapted for permanent attachment or removable attachment in the armpit area of a shirt. The shields are multi-layered fabrics that absorb perspiration, and in certain aspects, are used to control, reduce, or prevent perspiration from bleeding through and being shown on the outer surface of a garment. For example, these garments can include, but are not limited to, a multilayered fabric having at least a first fabric layer configured to wick moisture away from a person's body, at least a second fabric layer configured to absorb the moisture, and at least a third fabric layer that does not absorb moisture. As further described herein, various antimicrobial agents can be included in at least one fabric layer. These antimicrobial agents can be used to reduce or prevent the growth of microbes in and/or on the fabric, and these antimicrobial agents can be used to reduce or prevent odors derived from odor producing microbes.

Laminates suitable for constructing waterproof and breathable articles such as protective clothing which are both comfortable and exhibit enhanced resistance to fire are described. Particularly, flame resistant laminate constructions are described comprising a meltable textile as the outermost layer laminated to an intermediate protective layer comprising a waterproof film laminated to an innermost fabric layer comprising a thermally stable textile. Laminate constructions of the present invention exhibit breathability on the order of at least 1000 MVTR, a water entry pressure of at least 0.5 psi and have a horizontal flame break open time of at least 10 seconds.

A synthetic radiator fabric with permanent mechanical wicking defines an inner surface and has a raised knit body defining an opposite outer surface. The fabric includes hydrophilic and hydrophobic fiber-containing yarns. At the inner surface, the hydrophilic fiber-containing yarns collect liquid sweat from a wearer's skin surface and maintain the collected sweat at the inner surface, generally in the vicinity of and/or in contact with the wearer's skin, for encouraging evaporation of sweat and providing evaporative cooling. The raised knit body extends from the inner surface toward, and defines, the opposite outer surface. The hydrophobic fiber-containing yarns are arranged in a radiator-like construction forming egg-crate or honey-comb like cells or pores, defined by the knit body and open to the inner surface. At the outer fabric surface, the hydrophobic fibers receive excess sweat from the wearer's body, thereby to encourage rapid evaporation and drying, for improved breathability.

A synthetic radiator fabric with permanent mechanical wicking defines an inner surface and has a raised knit body defining an opposite outer surface. The fabric includes hydrophilic and hydrophobic fiber-containing yarns. At the inner surface, the hydrophilic fiber-containing yarns collect liquid sweat from a wearer's skin surface and maintain the collected sweat at the inner surface, generally in the vicinity of and/or in contact with the wearer's skin, for encouraging evaporation of sweat and providing evaporative cooling. The raised knit body extends from the inner surface toward, and defines, the opposite outer surface. The hydrophobic fiber-containing yarns are arranged in a radiator-like construction forming egg-crate or honey-comb like cells or pores, defined by the knit body and open to the inner surface. At the outer fabric surface, the hydrophobic fibers receive excess sweat from the wearer's body, thereby to encourage rapid evaporation and drying, for improved breathability.

In some embodiments, a heavyweight jacket includes a main body configured to fit on the torso of a wearer and sleeves that are fully detached from the main body. The sleeves advantageously facilitate putting on the heavy jacket, while providing a jacket of high weight. To form the heavyweight jacket, a pre-bonded fabric may be used. The fabric is pre-bonded and may optionally be further layered to increase the garment's weight without sacrificing flexibility or breathability. The layered fabric distributes the garment's weight evenly and ensures that the garment does not excessively restrict a wearer's freedom of movement or cause the wearer to overheat. The weight of the fabric may be increased by using a heavyweight glue to bond various layers of material together.

A glove for operating computer peripherals relieves stress and cramping and provides support for the wrist and hand. The glove includes an external non-slip surface located at the palm, an interior perspiration-absorbent area located at the palm, an open mesh area at the back of the hand, a substitutable supporting and cushioning wrist cuff that may be configured in height and viscosity by a user, and a tightening strap.

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.

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.

Fabrics made for apparel, tents, sleeping bags and the like, in various composites, constructed such that a combination of substrate layers and insulation layers is configured to provide improved thermal insulation. The fabric composites are constructed to form a radiant barrier against heat loss via radiation and via conduction from a body.

Fabrics made for apparel, tents, sleeping bags and the like, in various composites, constructed such that a combination of substrate layers and insulation layers is configured to provide improved thermal insulation. The fabric composites are constructed to form a radiant barrier against heat loss via radiation and via conduction from a body.