An artificial blood vessel and a method for preparing the same are disclosed. The method includes: weaving warp yarns and weft yarns to form interlaced first and second weaves, both weaves extend along a weft direction and alternate to obtain a composite fabric; and successively corrugating and thermal-setting the composite fabric to obtain the artificial blood vessel. In the composite structure of the artificial blood vessel with the alternating the first and second weaves formed by the warp and weft yarns, a softness degree of the first weave is lower than that of the second weave. As a result, combining stiffness of the first weave with softness of the second weave, this composite structure ensures both low permeability and increased softness of the fabric. Therefore, it is improved to a certain extent over the conventional woven artificial blood vessels and is easier to handle and suture.

Fabrics and garments are disclosed that have dual protection against molten metal splashes and electrical arc flashes. The fabrics can be made from spun yarns containing an intimate blend of fibers. The fibers contained in each yarn can include wool fibers, flame resistant cellulose fibers, and nylon fibers. In one aspect, relatively long wool fibers are incorporated into the yarns.

Fabrics and garments are disclosed that have dual protection against molten metal splashes and electrical arc flashes. The fabrics can be made from spun yarns containing an intimate blend of fibers. The fibers contained in each yarn can include wool fibers, flame resistant cellulose fibers, and nylon fibers. In one aspect, relatively long wool fibers are incorporated into the yarns.

The present invention provides an artificial bionic blood vessel and a manufacturing method thereof. The artificial bionic blood vessel includes a three-layer-structured artificial bionic blood vessel body, where the three-layer structure of the artificial bionic blood vessel consists of a natural silk layer, a diluted liquid silica-gel layer and a weaved tube layer, the diluted liquid silica-gel layer is located on the inner side of the natural silk layer, the weaved tube layer is located on the outer side of the natural silk layer, and the weaved tube layer is made of catgut by weaving.

The present invention provides an artificial bionic blood vessel and a manufacturing method thereof. The artificial bionic blood vessel includes a three-layer-structured artificial bionic blood vessel body, where the three-layer structure of the artificial bionic blood vessel consists of a natural silk layer, a diluted liquid silica-gel layer and a weaved tube layer, the diluted liquid silica-gel layer is located on the inner side of the natural silk layer, the weaved tube layer is located on the outer side of the natural silk layer, and the weaved tube layer is made of catgut by weaving.

A woven textile has one or more weavable threads and at least one lighting filament in which the weavable threads and the at least one lighting filament are woven together to form a textile with integrally woven lighting.

A novel fabric combination is provided to absorb electromagnetic radiation (ER) and electromagnetic field (EMF) waves. The fabric combination may be shaped into a wearable garment or an electronics case or cover. The fabric combination includes carbon yarn or carbon pieces, elastic yarn, and a soft yarn, such a wool or cotton. No metals configured to reflect ER and EMF waves are used, such as silver. The elastic yarn is a carbon stretch yarn made up of synthetic elastic fabric, such as spandex, and carbon fibers. The fabric combination absorbs ER and EMF waves from the environment, produced by electric devices, such as phones, laptops, tablet computers, microwaves, ovens, robots, 4G, 5G, Wi-Fi radiation, Bluetooth, or any other device or environmental sources emitting ER and EMF.

A novel fabric combination is provided to absorb electromagnetic radiation (ER) and electromagnetic field (EMF) waves. The fabric combination may be shaped into a wearable garment or an electronics case or cover. The fabric combination includes carbon yarn or carbon pieces, elastic yarn, and a soft yarn, such a wool or cotton. No metals configured to reflect ER and EMF waves are used, such as silver. The elastic yarn is a carbon stretch yarn made up of synthetic elastic fabric, such as spandex, and carbon fibers. The fabric combination absorbs ER and EMF waves from the environment, produced by electric devices, such as phones, laptops, tablet computers, microwaves, ovens, robots, 4G, 5G, Wi-Fi radiation, Bluetooth, or any other device or environmental sources emitting ER and EMF.

A fabric and a leather product in which collagen fiber bundles form a network structure has a base yarn woven layer, and also has collagen fiber bundles. The collagen fiber bundles sheathed in the base yarn woven layer protrude on the surface of the base yarn woven layer, and the protruding collagen fiber bundles and their branches are interwoven to form a network structure, where a part of the branches in the collagen fiber bundle is sheathed on the base yarn so that at least one end of the branch protrudes from the base yarn braided layer. Leather products may include these fabrics and leather surface layers.

A silk blend ballistic fabric for creating comfortable and flexible bulletproof apparel includes a plurality of silk threads and a plurality of para-aramid fiber threads interwoven with the plurality of silk threads to create a fabric. An alternative embodiment of the disclosure generally comprises a hybrid thread comprising a silk thread and a para-aramid fiber thread twisted with the silk thread. The resulting hybrid thread can be woven to create the fabric. The resulting fabric is bulletproof and substantially flexible to create articles of clothing such as, but not limited to, trousers, shirts, and the like.