The present invention relates to a method of producing a ribbon comprising bamboo fibers. The method comprises positioning the fibers on a conveyor and conveying the fibers in a transport direction, interconnecting the fibers by covering the fibers with thread and/or particles of a sticky material with at least one web forming device which is positioned above and/or below the conveyor and which ejects thread and/or particles. The formed thread and/or particles attaches to the fibers and forms a web which interconnects the fibers in order to form the ribbon and/or stitching the fibres together with at least one stitching device which is configured to stitch the individual fibers together in order to form the ribbon.

Disclosed is a dean production method for bamboo fibres, comprising the following steps: bamboo pieces are separated into filaments, and the filaments are twisted into ropes to obtain rope-shaped bamboo filaments; the rope-shaped bamboo filaments are refined by means of multiple alternating cold-hot treatments and rolling and rubbing to obtain coarse rope-shaped bamboo fibres (wherein same can be directly put into a drying device and then made into coarse bamboo fibres for a composite material); the coarse rope-shaped bamboo fibres are subjected to continuous biological degumming to obtain the rope-shaped bamboo fibres; the rope-shaped bamboo fibres are fed into a cleaning device for repeated cleaning, rolling and drying are performed, and then spraying-type oiling is performed to obtain thin rope-shaped bamboo fibres; finally, the thin rope-shaped bamboo fibres are subjected to opening and carding to make bamboo fibres for a textile material.

Disclosed is a dean production method for bamboo fibres, comprising the following steps: bamboo pieces are separated into filaments, and the filaments are twisted into ropes to obtain rope-shaped bamboo filaments; the rope-shaped bamboo filaments are refined by means of multiple alternating cold-hot treatments and rolling and rubbing to obtain coarse rope-shaped bamboo fibres (wherein same can be directly put into a drying device and then made into coarse bamboo fibres for a composite material); the coarse rope-shaped bamboo fibres are subjected to continuous biological degumming to obtain the rope-shaped bamboo fibres; the rope-shaped bamboo fibres are fed into a cleaning device for repeated cleaning, rolling and drying are performed, and then spraying-type oiling is performed to obtain thin rope-shaped bamboo fibres; finally, the thin rope-shaped bamboo fibres are subjected to opening and carding to make bamboo fibres for a textile material.

A superfine long bamboo filament production device comprises a bamboo filament processing machine, a baseplate, a material placement box and a material pushing box, wherein the bamboo filament processing machine is arranged on a left side of the baseplate, the material placement box is arranged above the baseplate, two mounting blocks are fixedly connected to front and rear outer side walls symmetrically, and a telescopic rod is fixedly connected to a bottom of each of the mounting blocks; the material pushing box is arranged between the baseplate and the material placement box, a discharge port is formed in a bottom of the material placement box, and is located directly above the material pushing box, a plurality of L-shaped rods are fixedly connected to an outer side wall of the material pushing box symmetrically, and the other end of each of the L-shaped rods is fixedly connected to the baseplate.

A superfine long bamboo filament production device comprises a bamboo filament processing machine, a baseplate, a material placement box and a material pushing box, wherein the bamboo filament processing machine is arranged on a left side of the baseplate, the material placement box is arranged above the baseplate, two mounting blocks are fixedly connected to front and rear outer side walls symmetrically, and a telescopic rod is fixedly connected to a bottom of each of the mounting blocks; the material pushing box is arranged between the baseplate and the material placement box, a discharge port is formed in a bottom of the material placement box, and is located directly above the material pushing box, a plurality of L-shaped rods are fixedly connected to an outer side wall of the material pushing box symmetrically, and the other end of each of the L-shaped rods is fixedly connected to the baseplate.

The present invention provides improved hemp decortication systems and methods, and include multi stage segmenting, cleaning, and combing methods and apparatus for separating fibrous plant stalk, and particularly for separating hemp bast fiber from hemp hurd.

The present invention provides improved hemp decortication systems and methods, and include multi stage segmenting, cleaning, and combing methods and apparatus for separating fibrous plant stalk, and particularly for separating hemp bast fiber from hemp hurd.

A continuous processing device for forming bamboo fiber includes a machine rail, a cart guide rail, a cart, and a clamp for clamping a bamboo strip. The cart and the clamp are connected through a connecting plate. The machine rail is formed with a slot along a path of the machine rail. The machine rail includes ahead linear rail section, a conical spiral rail section and a tail linear rail section arranged in sequence. The cart guide rail includes ahead linear guide rail section, a conical spiral guide rail section and a tail linear guide rail section arranged in sequence. A continuous processing method for forming bamboo fiber using the continuous processing device is disclosed. The present invention can quickly and efficiently produce a large quantity of high-quality bamboo fiber, greatly saving the production time of bamboo fiber, improving the production efficiency, and reducing the production cost.

A continuous processing device for forming bamboo fiber includes a machine rail, a cart guide rail, a cart, and a clamp for clamping a bamboo strip. The cart and the clamp are connected through a connecting plate. The machine rail is formed with a slot along a path of the machine rail. The machine rail includes ahead linear rail section, a conical spiral rail section and a tail linear rail section arranged in sequence. The cart guide rail includes ahead linear guide rail section, a conical spiral guide rail section and a tail linear guide rail section arranged in sequence. A continuous processing method for forming bamboo fiber using the continuous processing device is disclosed. The present invention can quickly and efficiently produce a large quantity of high-quality bamboo fiber, greatly saving the production time of bamboo fiber, improving the production efficiency, and reducing the production cost.

The present invention relates to a method of producing a ribbon comprising bamboo fibers. The method comprises positioning the fibers on a conveyor and conveying the fibers in a transport direction, interconnecting the fibers by covering the fibers with thread and/or particles of a sticky material with at least one web forming device which is positioned above and/or below the conveyor and which ejects thread and/or particles. The formed thread and/or particles attaches to the fibers and forms a web which interconnects the fibers in order to form the ribbon and/or stitching the fibres together with at least one stitching device which is configured to stitch the individual fibers together in order to form the ribbon.