A method of producing a hemp-blended single spun yarn may include: a fiber blending step of passing hemp fiber, together with latent crimped yarn fiber, through an opener in order to increase the cohesion of the hemp fiber by the three-dimensional chain structure, thereby producing a blended fiber including 10% to 60% latent crimped yarn fiber; a sliver production step of carding the blended fiber through a carding machine, and drafting the carded fiber through a drafting machine, thereby producing a sliver; and a spinning step of supplying the sliver as a roving yarn through a plurality of rollers to a twisting unit, and supplying a combined filament yarn, produced by twisting and having a structure in which a low-stretchability filament yarn surrounds a high-stretchability filament yarn, as a core yarn to the twisting unit without being passed through the plurality of rollers.

The present invention provides a method for successively introducing water soluble fibers into natural fibers (e.g. cotton) to produce a hollow and ultra soft structure, by introducing water soluble slivers into the center of a multi-hole feeder with multiple cotton fiber slivers arranged around the water soluble fiber in a pre-drawing process via a multi-hole sliver feeder. A cloth, e.g., made using the method.

The present invention provides a method for successively introducing water soluble fibers into finish fibers (e.g. cotton) to produce a hollow and ultra soft structure, by introducing water soluble slivers into the center of a fabric feeder with one or more cotton fiber slivers arranged around the water soluble fiber in a pre-drawing process via a fabric sliver feeder. A plurality of these fibers can be drawn together to produces a fiber having multiple water soluble fibers. A cloth, e.g., towel, can be made using the method.

A method 100 for processing fibrous matter from a waste material involves obtaining 101 the waste material, trimming 102 the waste material, pre-treating 104, second mechanical treatment 106, washing 108, first chemical treatment 110 with an enzyme and water solution, draining 112 the enzyme and water solution, heating 114 to obtain a fiber cake, providing 116 controlled shockwaves, a second chemical treatment 118, hydro-extracting 120 fiber cake, opening 122 the fiber cake, drying 124, pre-conditioning and softening 126, mechanically treating and segregating 128, softening 129, processing 130 to obtain a sliver and spinning 132 the sliver to obtain a product.

A method 100 for processing fibrous matter from a waste material involves obtaining 101 the waste material, trimming 102 the waste material, pre-treating 104, second mechanical treatment 106, washing 108, first chemical treatment 110 with an enzyme and water solution, draining 112 the enzyme and water solution, heating 114 to obtain a fiber cake, providing 116 controlled shockwaves, a second chemical treatment 118, hydro-extracting 120 fiber cake, opening 122 the fiber cake, drying 124, pre-conditioning and softening 126, mechanically treating and segregating 128, softening 129, processing 130 to obtain a sliver and spinning 132 the sliver to obtain a product.

A method for forming a copolyester material includes preparing a solution of monomers, applying a polymerization to form a copolyester having a low melting point, spinning the copolyester into fiber threads to form a copolyester fiber, weaving or knitting the copolyester fiber with a common fiber to form a composite cloth having a sheet shape, cutting the composite cloth to form a determined shape, applying a hot-press process on the composite cloth under a temperature of about 120 C. to 200 C., to release tackiness of the copolyester, so that the copolyester fiber and the common fiber are bonded tightly and closely, and forming a tough film on a surface of the composite cloth by the copolyester, so that the composite cloth has functions of stiffness and abrasion resistance by the tough film.

A method for forming a copolyester material includes preparing a solution of monomers, applying a polymerization to form a copolyester having a low melting point, spinning the copolyester into fiber threads to form a copolyester fiber, weaving or knitting the copolyester fiber with a common fiber to form a composite cloth having a sheet shape, cutting the composite cloth to form a determined shape, applying a hot-press process on the composite cloth under a temperature of about 120 C. to 200 C., to release tackiness of the copolyester, so that the copolyester fiber and the common fiber are bonded tightly and closely, and forming a tough film on a surface of the composite cloth by the copolyester, so that the composite cloth has functions of stiffness and abrasion resistance by the tough film.

A vortex tube system for conditioning and blending fibrous material utilizing a helical inlet to the base of a central vortex tube, to condition and blend fibers in a fluidly conveyed stream, and to separate the fibers from debris, by abruptly changing direction of the conveying air flow. The vortex tube system for conditioning and blending combines the helical input with helical shaping of the air flow through the central vortex tube to induce greater dynamics which is continued at the top of the vortex tube through a separate drying chamber.

A vortex tube system for conditioning and blending fibrous material utilizing a helical inlet to the base of a central vortex tube, to condition and blend fibers in a fluidly conveyed stream, and to separate the fibers from debris, by abruptly changing direction of the conveying air flow. The vortex tube system for conditioning and blending combines the helical input with helical shaping of the air flow through the central vortex tube to induce greater dynamics which is continued at the top of the vortex tube through a separate drying chamber.

A system and corresponding method are provided for controlling production in a blow room, the blow room including a controller, a supplying machine having a supplying part, and a machine to be supplied that has a filling level measurement. The supplying machine and the machine to be supplied are connected to the controller. A production area is defined for the supplying machine and includes a minimum production and a maximum production. Production of the supplying part of the supplying machine is determined based on a filling level of the filling level measurement. When production of the production area drops below the minimum production, the supplying part of the supplying machine is shut down, the shutdown taking place independently of the filling level of the machine to be supplied.