In the process of preparing nanofibers by using an electrospinning process and preparing micron fibers by using a flash-spinning process, an electrospinning nozzle and a flash-spinning nozzle are controlled to be located above a receiving conveyor belt, and are directly opposite to each other with a spacing of 15-40 cm, and the electrospinning nozzle is controlled to be connected to a high-voltage power supply, and the flash-spinning nozzle and the receiving conveyor belt are controlled to be grounded to prepare a product; the prepared product has a film-like structure and consists of nanofibers and micron fibers. The micron fibers are mutually entangled, curled and interpenetrated, and the nanofibers are uniformly interspersed and distributed within the micron fibers, some of the nanofibers and the micron fibers forming entangled and interpenetrated structures, with mutual bonding between the nanofibers, between the micron fibers and between the nanofibers and the micron fibers.

Provided are a method for producing a carbon fiber bundle composite and a carbon fiber bundle composite. The method contains a step of mixing carbon fiber fluff made of short carbon fibers and a molten resin containing an epoxy resin component to obtain a carbon fiber bundle containing the molten resin, a step of solidifying the molten resin, and a step of mixing at least one type of epoxy curing agent into the molten resin. The carbon fiber bundle composite contains a plurality of short carbon fibers forming the bundle and an uncured solid epoxy resin composition. The positions of the tips of the short carbon fibers are uneven at each end of the bundle; and the uncured solid epoxy resin composition contains at least one type of epoxy curing agent.

Provided is a nonwoven fabric for skin care products. The nonwoven fabric includes: a thermoplastic resin fiber having a single fiber diameter of 50 nm or more and 800 nm or less; and a cellulose fiber. A tensile strength of the cellulose fiber measured in accordance with JIS L 1015:2010 8.7.2 is 1.9 cN/dtex or less, a total content of the thermoplastic resin fiber and the cellulose fiber is 85% by mass or more relative to a total mass of the nonwoven fabric for skin care products, a content ratio by mass of the thermoplastic resin fiber and the cellulose fiber (thermoplastic resin fiber/cellulose fiber) is 0.23 to 1.50, and a density of the nonwoven fabric for skin care products is 0.08 g/cm.sup.3 to 0.16 g/cm.sup.3.

Provided is a hyaluronate non-woven fabric made of hyaluronate fibers and a method of manufacturing the same. More particularly, the present invention relates to a highly functional hyaluronate non-woven fabric made of hyaluronate fibers having a rough surface and a micro-size diameter and a method of manufacturing the same. A hyaluronate non-woven fabric manufacturing method according to the present invention includes preparing hyaluronate fibers, treating the hyaluronate fibers to be curled, cutting the curled hyaluronate fibers, forming a hyaluronate web from the curled hyaluronate fibers, and needle-punching the hyaluronate web. The hyaluronate non-woven fabric of the present invention has a high hyaluronate content, is manufactured by needle punching high-strength hyaluronate fibers, and has excellent adhesion and tensile strength. Therefore, the hyaluronate non-woven fabric of the present invention can be used as a mask pack for external application on the skin, a biomaterial for tissue repairing, and an anti-adhesion coating material.

A method for producing a filling material comprising goose and/or duck down and vegetable kapok fibres comprises feeding vegetable kapok fibre to a mixing chamber (16), separating elementary kapok filaments (210) unbound from each other from the vegetable kapok fibre in the mixing chamber (16) by directing jets and/or blades of a pressurized fluid against the vegetable kapok fibre, feeding goose and/or duck down to the mixing chamber (16) and incorporating elementary kapok filaments (210) unbound from each other into the flakes (101) of goose and/or duck down (100) by mixing the elementary kapok filaments (210) and the goose and/or duck down in the mixing chamber (16) by means of said jets and/or blades of pressurized fluid fed for example by suitably oriented nozzles (33).

A composite structure includes a number of fiber layers. Each fiber layer of the number of fiber layers includes a fiber bundle and a filament layer at least partially covering the fiber bundle. The filament layer includes discontinuous filaments. The discontinuous filaments include at least one of different length filaments, including first length filaments and second length filaments. The first length filaments include a first length and the second length filaments include a second length. The first length is different than the second length. The discontinuous filaments include at least one of different type filaments, including first type filaments and second type filaments. The first type filaments include a first material composition. The second type filaments include a second material composition. The first material composition is different than the second material composition. The composite structure includes a resin binding the number of fiber layers together.

An energy control system comprising one or more fibers, the one or more fibers each comprising strain-rate sensitive material. Wearable items comprising the energy control system. A method of manufacturing a strain-rate sensitive fiber, the method comprising: extruding strain-rate sensitive material to form one or more fibers; coating the extruded one or more fibers with a tackiness reducing powder; and applying the coated one or more fibers onto a storage component. A method of manufacturing a strain-rate sensitive fiber, the method comprising: extruding strain-rate sensitive material to form one or more fibers; reducing tension on the extruded one or more fibers; and applying the reduced tension one or more fibers onto a storage component. A protection element configured to at least partially enclose one or more elongate elements, the protection element comprising strain-rate sensitive material.

An antibacterial and antiviral degradable mask and a manufacturing method thereof are provided. From outside to inside, the mask sequentially comprises a surface layer (1), a core layer (2), and an inner layer (3) that contacts the face; the surface layer (1) is made of an antibacterial and antiviral cellulose spunlace non-woven fabric; the core layer (2) is made of a polypropylene melt-blown non-woven fabric; the inner layer (3) is made of a polypropylene spunbond non-woven fabric or a degradable natural cotton fabric. The mask can have both antibacterial and antiviral functions; moreover, the material is degradable, and thus, environmental pollution pressure caused by non-degradable petroleum-based fiber materials such as polypropylene can be effectively relieved.

A fiber structure manufacturing apparatus includes: a defibrated material supplying unit that supplies a defibrated material obtained by defibrating a material that contains fibers; a resin supplying unit that supplies resin fibers; a mixing unit; an accumulation unit; and a shape molding unit, wherein the resin supplying unit includes a fragmenting unit that produces resin fiber fragments by performing fragmentation of a cotton-like lump of the resin fibers, a constant amount supplying unit that supplies a constant amount of the resin fiber fragments produced by the fragmenting unit, a loosening unit that loosens the resin fiber fragments supplied from the constant amount supplying unit to decrease density of the resin fiber fragments, and a transferring unit that transfers the resin fibers like a cotton loosened by the loosening unit to the mixing unit.

Soft and strong nonwoven web materials and methods of formation are described. In one embodiment, a method of forming a web may comprise merging a stream of an absorbent material with streams of meltblown fibers, the streams of meltblown fibers comprising bicomponent fibers formed of a first polymer component and a second polymer component, collecting the merged stream onto a forming surface, merging a stream of an absorbent material with streams of meltblown fibers, the streams of meltblown fibers comprising monocomponent fibers formed of the first polymer component or a third polymer component, collecting the merged stream onto the collected merged stream disposed on the forming surface, merging a stream of an absorbent material with streams of meltblown fibers, the streams of meltblown fibers comprising bicomponent fibers, and collecting the merged stream onto the collected merged streams to form the stratified nonwoven web material.