The present disclosure provides a high thread/yarn count textile fabric and a process of preparation thereof. The textile includes a plurality of warps and a plurality of wefts, wherein warp includes a plurality of separable multi-filament yarn. Each yarn has a denier in the range of 5 to 30. The textile fabric has a total thread/yarn count in the range of 300 to 3000 thread/yarns per inch. Each of the plurality of warps comprises 250 to 3000 ends per inch. The present disclosure uses a simple and direct process to achieve good quality textile having a high thread/yarn count at low production cost.

The present disclosure provides a high thread/yarn count textile fabric and a process of preparation thereof. The textile includes a plurality of warps and a plurality of wefts, wherein warp includes a plurality of separable multi-filament yarn. Each yarn has a denier in the range of 5 to 30. The textile fabric has a total thread/yarn count in the range of 300 to 3000 thread/yarns per inch. Each of the plurality of warps comprises 250 to 3000 ends per inch. The present disclosure uses a simple and direct process to achieve good quality textile having a high thread/yarn count at low production cost.

The present application discloses a method of manufacturing a fabric. The method comprises warping a yarn; sizing the yarn with a strengthening agent; weaving the yarn; greying the yarn to form a prototype of the fabric; desizing the strengthening agent; adding a quick-drying agent on the prototype; and drying the prototype to form the fabric. In addition, before or after adding a quick-drying agent on the prototype, the method further comprises adding an anti-bacterial agent or an anti-ultraviolet agent on the prototype.

The present application discloses a method of manufacturing a fabric. The method comprises warping a yarn; sizing the yarn with a strengthening agent; weaving the yarn; greying the yarn to form a prototype of the fabric; desizing the strengthening agent; adding a quick-drying agent on the prototype; and drying the prototype to form the fabric. In addition, before or after adding a quick-drying agent on the prototype, the method further comprises adding an anti-bacterial agent or an anti-ultraviolet agent on the prototype.

A new, rapid and inexpensive synthesis method for monodispersed triaminotrinitrobenzene (TATB) microparticles based on micelle-confined precipitation that enables control of microscopic morphology. The morphology of the TATB microparticles can be tuned between quasi-spherical and faceted by controlling the speed of recrystallization. The method enables improved performance and production consistency of TATB explosives for military grade explosives and propellants

A wrappable textile sleeve for protecting an elongate member and method of construction thereof is provided. The sleeve includes a plurality of warp filaments and at least one weft filament woven with one another to form a woven wall. The woven wall has opposite sides extending lengthwise between opposite ends. The opposite sides are wrappable about a central longitudinal axis into overlapping relation with one another to bound the elongate member within a cavity of the sleeve. At least one warp and/or weft filament is provided as a bulky, fluffy multifilament, wherein the bulky, fluffy multifilament is woven to form at least one float extending over 2 or more weft and/or warp yarns, wherein the at least one float provides loops sufficient to readily fix themselves to hooks of a standard hook and loop fastener.

A wrappable textile sleeve for protecting an elongate member and method of construction thereof is provided. The sleeve includes a plurality of warp filaments and at least one weft filament woven with one another to form a woven wall. The woven wall has opposite sides extending lengthwise between opposite ends. The opposite sides are wrappable about a central longitudinal axis into overlapping relation with one another to bound the elongate member within a cavity of the sleeve. At least one warp and/or weft filament is provided as a bulky, fluffy multifilament, wherein the bulky, fluffy multifilament is woven to form at least one float extending over 2 or more weft and/or warp yarns, wherein the at least one float provides loops sufficient to readily fix themselves to hooks of a standard hook and loop fastener.

The present invention generally concerns a method for isolating nanoparticles via the decomposition of a ternary metal hydride. More specifically, the present invention harnesses increased energy densities from two distinct nanoparticles isolated by a precise decomposition of LiAlH.sub.4. The singular material is air stable and is a nanocomposite of Li.sub.3AlH.sub.6 nanoparticles, elemental Al nanoparticles, an amount of Ti metal, and a nanoscale organic layer, which we call nMx. The nanocomposite protects and preserves the high energy densities of the core metals isolated from the controlled reaction and makes the nanoparticles safe to handle in air. The final composite is devoid of byproducts or phase transitions that will decrease the energy output of the nanocomposite. The method of the present invention creates a narrow distribution of nanoparticles that have unique burning characteristics useful for many applications.

An ultra-soft fabric and a process of manufacturing the ultra-soft fabric is described. The ultra-soft fabric is made from polyester staple fiber and high-tenacity, man-made cellulosic staple fiber, and fabrics made therefrom, and has particular reference to fabrics having a high resistance to wear while retaining a high comfort level. Another embodiment improves the durability of the ultra-soft fabric.

An ultra-soft fabric and a process of manufacturing the ultra-soft fabric is described. The ultra-soft fabric is made from polyester staple fiber and high-tenacity, man-made cellulosic staple fiber, and fabrics made therefrom, and has particular reference to fabrics having a high resistance to wear while retaining a high comfort level. Another embodiment improves the durability of the ultra-soft fabric.