A molding process (100) comprising the step of inserting an uncured blank (102) in a mold cavity (14) formed in a mold system, the uncured blank including fiber and uncured binder, transferring heat from the mold system to a cool pressurized gas (108) to establish a hot pressurized gas, injecting the hot pressurized gas into the mold cavity (110), and transferring heat (112) from the hot pressurized gas to the uncured blank to cause the uncured binder to cure and establish a cured product (114).

A molding process includes the operation of placing insulation material comprising fibers and binder on the fibers in a mold cavity. The molding process further includes the step of transferring heat to the insulation material to cause the binder to cure.

A process for fabricating a three-dimensional, multi-layered fabric product with a moisture barrier is provided. A partially seamed inner lining fabric assembly having at least a two-dimensional shape is laminated with a membrane barrier film having flaps left un-laminated to cover at least one seam. The inner lining fabric assembly is further seamed and flaps of the of the membrane barrier film overlapped into contact with each other and sealed to provide a continuous moisture barrier. A process for fabricating a stretchable section of a garment with a moisture barrier is also provided. At least a section of a garment is formed from fibers arranged in a pattern having a direction of stretch in one direction and a three-dimensional surface texture such that a portion of the fibers protrude above another portion of the fibers. The stretchable section is stretched in the direction of stretch. Segments of a membrane barrier film are adhered to an outer edge of the protruding portion of the fibers while the section is stretched in the direction of stretch, leaving intermediate segments of the barrier film free from adherence to the section. In this way, the intermediate segments of the membrane barrier film include slack that folds up to form ruches when the section is in a relaxed state.

Surface protection systems can be applied when the protection of flooring surfaces from contaminates is desired or required to maintain their integrity and appearance. Surface protection systems can be highly storable when rolled up and held together with, for example, integrated straps. When needed, it can be unrolled and placed onto aircraft flooring (or other surfaces) to provide a waterproof, absorbent, slip resistant and adjustable barrier.

The disclosed embodiments include a blend of bison fibers, another fiber, and adhesives. The bison fibers are sheared from a bison, scoured, dehaired, blended with various other fibers and/or compositions, carded, and manufactured into insulation. The bison hairs can be categorized by diameter into one of four categories: prime, drop A, drop B, or drop C. Furthermore, bison fiber can be categorized based on length, coarseness, weight, and/or where on the bison it was sheared from. The insulation can be batted, woven, knit, loose, and/or other similar types. The insulation can be used for garments, outdoor equipment, bedding products, and/or other products. The weight of the insulation can be between 40 grams per square meter and 500 grams per square meter. The bison fiber can be blended with recycled polyester, bison fiber, wool, bast fiber, cellulose fiber, and/or synthetic fiber. The adhesives can be low-melt poly, or resin.

An insulated container may include a rigid container surrounding an insulation layer formed from a post-industrial, pre-consumer card waste. The insulation layer may be characterized by a lack of any wrapping material. The insulation layer may be manufactured using a variety of converting processes including, carding, airlay, and needle punch to form a non-woven material for providing consistent density throughout the insulation layer. The insulation layer may include a natural fiber lamination layer on an outer surface of the insulation layer. The insulation layer may be biodegradable in an anaerobic environment.

A fire barrier fabric includes a first layer including a fleece, flame-retardant cellulosic fibers and a binder; and a second layer including flame-retardant cellulosic fibers and a binder. The fleece may include natural crimped wool. The fleece may include one or more of sheep wool fleece, alpaca wool fleece, cashmere wool fleece, and silk fleece. The flame-retardant cellulosic fibers may be inherently flame-retardant cellulosic fibers. The flame-retardant cellulosic fibers may include one or more of treated flame-retardant cotton fibers, flame-retardant bamboo fibers, flame-retardant viscose fibers, flame-retardant rayon fibers, and flame-retardant silica-filled viscose fibers.

The present invention relates to a V-ribbed belt in which a frictional power-transmission surface is formed from a weft knitted multilayer knitted fabric, characterized in that the weft knitted multilayer knitted fabric contains cellulose based natural spun yarn, polyester based composite yarn, and polyamide based yarn, and in that at least the cellulose based natural spun yarn and the polyamide based yarn are disposed in a layer on the frictional power-transmission surface side.

A V-ribbed belt in which a frictional power-transmission surface is formed from a weft knitted multilayer knitted fabric is provided, in which the weft knitted multilayer knitted fabric contains cellulose based natural spun yarn, polyester based composite yarn, and polyamide based yarn, and in that at least the cellulose based natural spun yarn and the polyamide based yarn are disposed in a layer on the frictional power-transmission surface side.

A personal protective equipment face covering includes at least one layer. Each of the at least one layers includes at least one fabric material. Wherein, each of the at least one layers of the at least one fabric material including an inherently ionic material. Wherein an ionic charge on the inherently charged ionic material comes from a molecular structure, not from electrostatic charge or triboelectricity.