A thermal camouflage fabric has a first side and a second side and at least the first side of the fabric comprises a printed layer. The printed layer contains at least a first, second, and third color paste in a camouflage pattern. At least a portion of the first, second, and third color pastes are in discrete locations in the printed layer. The first, second, and third color pastes each contain at least one pigment, a plurality of metallic particles, and a binder. The first color paste contains at least about twice the amount by weight of metallic particles than the third color paste and the first color paste contains less pigment by weight than the third color paste.

A method of manufacturing camouflage clothing worn by soldiers is provided. The optimum camouflage clothing satisfying clothing functionality, aesthetics, and camouflaging effect, which is an important function for military uniforms, is provided while the optimum camouflage clothing is economical. The camouflage clothing is formed by dyeing threads i.e. row material, using the dyed threads as warp threads and weft threads, and weaving the camouflage clothing using a jacquard weaving machine. Herein, the warp threads and the weft threads are gradationally arranged to form a delicate-colored checked pattern while a three-dimensional pattern is displayed by the jacquard weaving machine.

The invention addresses the problem of providing a cloth that is excellent not only in flame retardancy and antistatic properties but also in appearance quality and preferably also has protection performance against electric arcs, a method for producing the same, and a textile product. A means for resolution is a cloth including a meta-type wholly aromatic polyamide fiber and an electrically conductive fiber, wherein both the meta-type wholly aromatic polyamide fiber and the electrically conductive fiber are colored.

A metalized fabric and method for metallization of fabric. The fabric is formed using two threads with different affinities for metallization, but which threads are not metalized prior to forming into the fabric. The threads will typically be woven using an unbalanced weave to provide one side of the fabric with a resultant greater amount of metallization than the other but this is not required. Once the resultant fabric is metalized, it will typically be more suitable for consistent color dying than fabric which was formed from both metalized and unmetallized threads.

A mesh material for fabricating hunting blinds, tents, and other similar flexible structures. The material is durable, water-resistant, and partially light-transmissive such that persons or objects inside or behind the structures are not easily seen from outside the structures. The material is also semi-permeable to air flow for ventilation purposes. The mesh material is fabricated from an interwoven polyester, polyurethane, or polyvinyl chloride (PVC) fabric that is coated with acrylic and a mixture of silicone and ethylene vinyl acetate (EVA). Patterns and/or colors are printed on both sides of the fabric with a heat transfer paper printing process to provide a desired level of light transmissivity.

A mesh material for fabricating hunting blinds, tents, and other similar flexible structures. The material is durable, water-resistant, and partially light-transmissive such that persons or objects inside or behind the structures are not easily seen from outside the structures. The material is also semi-permeable to air flow for ventilation purposes. The mesh material is fabricated from an interwoven polyester, polyurethane, or polyvinyl chloride (PVC) fabric that is coated with acrylic and a mixture of silicone and ethylene vinyl acetate (EVA). Patterns and/or colors are printed on both sides of the fabric with a heat transfer paper printing process to provide a desired level of light transmissivity.

A mesh material for fabricating hunting blinds, tents, and other similar flexible structures. The material is durable, water-resistant, and partially light-transmissive such that persons or objects inside or behind the structures are not easily seen from outside the structures. The material is also semi-permeable to air flow for ventilation purposes. The mesh material is fabricated from an interwoven polyester fabric that is coated with acrylic and a mixture of silicone and ethylene vinyl acetate (EVA). Patterns and/or colors are printed on both sides of the fabric with a heat transfer paper printing process to provide a desired level of light transmissivity.

In accordance with one embodiment of the present invention, a method of multi-use multi-vision modular covers comprising of aggregating multiple devices into physical meshes and virtual networks where devices exchange multi-source data transactions and transmissions between meshed devices to project on their respective screens the exchanged images, videos, and/or visual adjustments to produce multiple video See Through streams between meshed devices in static states and/or in motion. In a preferred embodiment, the invention is combination of devices, cameras, and/or screens that produce See-Through video streams with enhancements to hide, protect, and sustain modular permutations of invisible armors, invisible cloaks, invisible vehicles, invisible crafts, invisible land drones, invisible flying drones, invisible camo nettings, and other invisible configurations managed by manager-of-manager portal platforms that can provision, manage, and monitor all these configurations and deployments during a battle while producing synergies of invisible combined arms tactics to defeat the enemies of God.

A mesh material for fabricating hunting blinds, tents, and other similar flexible structures. The material is durable, water-resistant, and partially light-transmissive such that persons or objects inside or behind the structures are not easily seen from outside the structures. The material is also semi-permeable to air flow for ventilation purposes. The mesh material is fabricated from an interwoven polyester fabric that is coated with acrylic and a mixture of silicone and ethylene vinyl acetate (EVA). Patterns and/or colors are printed on both sides of the fabric with a heat transfer paper printing process to provide a desired level of light transmissivity.

The invention addresses the problem of providing a cloth that is excellent not only in flame retardancy and antistatic properties but also in appearance quality and preferably also has protection performance against electric arcs, a method for producing the same, and a textile product. A means for resolution is a cloth including a meta-type wholly aromatic polyamide fiber and an electrically conductive fiber, wherein both the meta-type wholly aromatic polyamide fiber and the electrically conductive fiber are colored.