The garments disclosed herein have integrated gripping technology to grip the body of the wearer over large interior surfaces. The distribution of gripping technology throughout the garment gives increased freedom of body movement and reduces bulkiness over conventional garments, while also allowing for free cut edges. Furthermore, the dispersion of the gripping technology over the majority of the garment eliminates the problem of polymer strips and beading digging into the skin. Slip garment embodiments are disclosed herein that include a lower region having an interior surface with exposed elastic threads configured to directly contact the wearer. The slip garment embodiments include a free-cut lower edge. The slip garment embodiments can be constructed using cut and sew methods.

Provided is a compression garment formed of a stretchable woven fabric with a uniform elasticity, such as denim. A circumferential portion of the garment surrounds a wearer's body part and is characterized by different degree of stretching but the same circumferential compressive forces when worn by a wearer, at various axial locations due to geometric cuts made to the fabric to form one or more fabric panels, each of which extend along the entire length of the circumferential portion. The compressive forces, degrees of stretching and circumferential lengths of fabric, are calculated using formulas and algorithms that take into account various factors relating to the fabric and the garment being formed.

Provided is a compression garment formed of a stretchable woven fabric with a uniform elasticity, such as denim. A circumferential portion of the garment surrounds a wearer's body part and is characterized by different degree of stretching but the same circumferential compressive forces when worn by a wearer, at various axial locations due to geometric cuts made to the fabric to form one or more fabric panels, each of which extend along the entire length of the circumferential portion. The compressive forces, degrees of stretching and circumferential lengths of fabric, are calculated using formulas and algorithms that take into account various factors relating to the fabric and the garment being formed.

Fabrics comprising regenerated cellulose fibers and a nanoparticle dispersed throughout the fabric are disclosed herein. The regenerated cellulose fibers can be derived from a biomass such as a fibrous cellulose, wood pulp, cotton, paper, bast fiber, bagasse, or a combination thereof. The nanoparticle included in the fabric can be chosen to confer a desirable property, such as a thermal insulating property, to the fabric. Methods of making the fabrics comprising the regenerated cellulose fibers and nanoparticle are also provided. The method can include (a) at least partially dissolving a cellulose substrate in a medium comprising one or more ionic liquids; and dissolving or suspending a nanoparticle in the medium; (b) recovering a solid nanoparticle-modified regenerated cellulose material comprising the cellulose substrate and the nanoparticle; and (c) processing the solid nanoparticle-modified regenerated cellulose material to form the fabric.

Articles of wear having one or more textiles that include a low processing temperature polymeric composition and a high processing temperature polymeric composition, and methods of manufacturing the same are disclosed. The low processing temperature polymeric composition and the high processing temperature polymeric composition can be selectively incorporated into a textile to provide one or more structural properties and/or other advantageous properties to the article. The textile can be thermoformed to impart such structural and/or other advantageous properties to the article of wear. This abstract is intended as a scanning tool for purposes of searching in the particular art and is not intended to be limiting of the present disclosure.

Articles of wear having one or more textiles that include a low processing temperature polymeric composition and a high processing temperature polymeric composition, and methods of manufacturing the same are disclosed. The low processing temperature polymeric composition and the high processing temperature polymeric composition can be selectively incorporated into a textile to provide one or more structural properties and/or other advantageous properties to the article. The textile can be thermoformed to impart such structural and/or other advantageous properties to the article of wear. This abstract is intended as a scanning tool for purposes of searching in the particular art and is not intended to be limiting of the present disclosure.

Disclosed is a fabric having a first side and a second side, that is provided at least on part of the first side with a pattern of protrusions, wherein the protrusions comprise an expanded heat-expanding material, namely a heat-expanding material that has been expanded by heating. A polymeric layer is provided to the woven fabric to coat at least part of the protrusions. Also disclosed is a process for the production of the fabric and a garment comprising the fabric.

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.

A wearable airfoil garment for reducing the cyclist aerodynamic drag. A garment material is elastically tethered between two or more anchor locations on the garment. The anchor locations are positioned and arranged to form transient, self-adaptive, body-conforming airfoil surfaces on the garment. The self-adjustment of the airfoil surfaces preserves the cyclist's comfort as well as the aerodynamic efficiency. The airfoil surfaces change in a body-conforming manner in response to the movements of a person wearing the garment. The aerodynamic performance of the garment is adjustable to the preference of the wearer. Garment airfoils constructed with seams suitably placed to trigger transition of boundary layers.