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 disclosure is broadly concerned with processing equipment and methods for processing of a biomass feedstock into one or more biomass particles of reduced size, and in particular, hemp. The vertical impact liberating equipment and methods can process whole hemp stalks into hemp particulates comprising distinct fractions of hemp hurds, bast fiber, and fines. Advantageously, in preferred embodiments, the biomass feedstock is pulled through a defined gap and into a defined chamber. This action causes a successive decrease and increase of pressure within the biomass feedstock, yielding the one or more biomass particles of reduced size.

The present disclosure is broadly concerned with processing equipment and methods for processing of a biomass feedstock into one or more biomass particles of reduced size, and in particular, hemp. The vertical impact liberating equipment and methods can process whole hemp stalks into hemp particulates comprising distinct fractions of hemp hurds, bast fiber, and fines. Advantageously, in preferred embodiments, the biomass feedstock is pulled through a defined gap and into a defined chamber. This action causes a successive decrease and increase of pressure within the biomass feedstock, yielding the one or more biomass particles of reduced size.

The present disclosure is broadly concerned with processing equipment and methods for processing of a biomass feedstock into one or more biomass particles of reduced size, and in particular, hemp. The vertical impact liberating equipment and methods can process whole hemp stalks into hemp particulates comprising distinct fractions of hemp hurds, bast fiber, and fines. Advantageously, in preferred embodiments, the biomass feedstock is pulled through a defined gap and into a defined chamber. This action causes a successive decrease and increase of pressure within the biomass feedstock, yielding the one or more biomass particles of reduced size.

The present disclosure is broadly concerned with processing equipment and methods for processing of a biomass feedstock into one or more biomass particles of reduced size, and in particular, hemp. The vertical impact liberating equipment and methods can process whole hemp stalks into hemp particulates comprising distinct fractions of hemp hurds, bast fiber, and fines. Advantageously, in preferred embodiments, the biomass feedstock is pulled through a defined gap and into a defined chamber. This action causes a successive decrease and increase of pressure within the biomass feedstock, yielding the one or more biomass particles of reduced size.

A plant stalk decorticator includes a pair of feed rollers arranged abutting one another along a substantially horizontal axis with a line of contact therebetween. A splitting wedge is positioned at least partially below the pair of feed rollers and aligned along a substantially vertical axis that is substantially centrally located in the line of contact between the pair of feed rollers, the splitting wedge is configured to split a plant stalk fed from the pair of feed rollers into two plant fiber bark sections. Symmetrical pairs of vertically stacked peeling rollers are positioned below the pair of feed rollers and laterally from either side of the substantially vertical axis. Each of the pairs of peeling rollers are configured to receive a respective one of the plant fiber bark sections from the splitting wedge and separate the plant fiber bark section from the respective other one of the plant fiber bark sections.

A plant stalk decorticator includes a pair of feed rollers arranged abutting one another along a substantially horizontal axis with a line of contact therebetween. A splitting wedge is positioned at least partially below the pair of feed rollers and aligned along a substantially vertical axis that is substantially centrally located in the line of contact between the pair of feed rollers, the splitting wedge is configured to split a plant stalk fed from the pair of feed rollers into two plant fiber bark sections. Symmetrical pairs of vertically stacked peeling rollers are positioned below the pair of feed rollers and laterally from either side of the substantially vertical axis. Each of the pairs of peeling rollers are configured to receive a respective one of the plant fiber bark sections from the splitting wedge and separate the plant fiber bark section from the respective other one of the plant fiber bark sections.

System for manufacturing bamboo fibers from bamboo parts, the system comprising: at least one milling device (12) configured for milling the bamboo parts into bamboo fibers, and at least one diameter sieve device (18) configured for separating the bamboo fibers in a first width fraction of relatively narrow bamboo fibers and a second width fraction of relatively wide bamboo fibers, wherein the bamboo fibers of the second width fraction have a greater diameter than the bamboo fibers of the first width fraction.

System for manufacturing bamboo fibers from bamboo parts, the system comprising: at least one milling device (12) configured for milling the bamboo parts into bamboo fibers, and at least one diameter sieve device (18) configured for separating the bamboo fibers in a first width fraction of relatively narrow bamboo fibers and a second width fraction of relatively wide bamboo fibers, wherein the bamboo fibers of the second width fraction have a greater diameter than the bamboo fibers of the first width fraction.