A high thread/yarn count textile fabric and a process of preparation thereof. The textile comprises a plurality of Warps and a plurality of Wefts, wherein Warp comprises a plurality of separable multi-filament Yarns. 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.

A high thread/yarn count textile fabric and a process of preparation thereof. The textile comprises a plurality of Warps and a plurality of Wefts, wherein Warp comprises a plurality of separable multi-filament Yarns. 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 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.

A high thread/yarn count textile fabric and a process of preparation thereof. The textile comprises a plurality of Warps and a plurality of Wefts, wherein Warp comprises a plurality of separable multi-filament Yarns. 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.

A high thread/yarn count textile fabric and a process of preparation thereof. The textile comprises a plurality of Warps and a plurality of Wefts, wherein Warp comprises a plurality of separable multi-filament Yarns. 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.

A graphene oxide/polypropylene heat-resistant high-strength composite profile and a preparation method thereof. The composite profile is a graphene oxide/polypropylene-based reinforced plain weave composite resin material, which is a heat-resistant high-strength composite profile prepared from a graphene oxide/polypropylene-based woven plain weave fabric and a fiber heat-insulating material which are made into a layered spacing structure composite flat net, and a resin composite material. The preparation method comprises the following steps: preparation of a graphene oxide/polypropylene-based woven plain weave fabric; preparation of a graphene oxide/polypropylene-based reinforced plain weave composite material; preparation of a multilayer graphene oxide/polypropylene-based reinforced plain weave composite material; and preparation of a resin composite material. The present invention has the advantages of convenient operation and excellent properties.

A graphene oxide/polypropylene heat-resistant high-strength composite profile and a preparation method thereof. The composite profile is a graphene oxide/polypropylene-based reinforced plain weave composite resin material, which is a heat-resistant high-strength composite profile prepared from a graphene oxide/polypropylene-based woven plain weave fabric and a fiber heat-insulating material which are made into a layered spacing structure composite flat net, and a resin composite material. The preparation method comprises the following steps: preparation of a graphene oxide/polypropylene-based woven plain weave fabric; preparation of a graphene oxide/polypropylene-based reinforced plain weave composite material; preparation of a multilayer graphene oxide/polypropylene-based reinforced plain weave composite material; and preparation of a resin composite material. The present invention has the advantages of convenient operation and excellent properties.

A training aid for use in training canines to detect an explosive material includes an explosive material adsorbed in the pores of a high surface area mesoporous or nanoporous host material. By adjusting the surfaces of the pores of the substrate material, the substrate can accommodate various types of explosive materials in a non-detonable and non-flammable manner, including nitroaromatics, nitroamines, nitrate-based explosives, and peroxide-based explosives. When the training aid is in an unsealed condition, a continuous flux of explosive material is released without providing any explosive or flame hazard to the trainer and canine.

Provided is a multiple gauze fabric having excellent friction strength while maintaining skin feel like twistless yarn fabric. The multiple gauze fabric is constituted from a first gauze structure as a front surface, a second gauze structure as a back surface, and a third gauze structure as an intermediate layer. The first gauze structure is formed using a first twisted yarn as a warp, and using a second twisted yarn as a weft. The second gauze structure is formed using a third twisted yarn as a weft, and a fourth twisted yarn as a warp. The third gauze structure is formed using a fifth twisted yarn as a warp, and a sixth twisted yarn as a weft. The twist coefficient of second and fourth twisted yarn is 3.0 or less. The twist coefficient of first, third, fifth and sixth twisted yarn is 3.3 or more.