The invention relates to a spider-silk-like polymer fiber in the technical field of chemical bionics, a preparation method therefor and the use thereof. The spider-silk-like polymer fiber comprises a matrix polymer and a particle additive dispersed therein, wherein the particles have an average particle size of 0.1-1000 microns, and the polymer fiber has a spider-silk-like microstructure comprising a fiber body and spaced spindle knot structural units on the fiber body, wherein the spindle knot structural units comprise the particles, and the radial height of the spindle knot structural units is greater than the diameter of the fiber body. The preparation method of the polymer fiber of the invention does not require greatly modifying the existing spinning processes, and the equipment does not need to be changed, the process is simple, and the cost is low. The obtained spider-silk-like polymer fiber can realize the directional movement of water droplets on the surface of the fiber, thereby having a water gathering function and can be used for preparing water gathering materials.

The invention relates to a spider-silk-like polymer fiber in the technical field of chemical bionics, a preparation method therefor and the use thereof. The spider-silk-like polymer fiber comprises a matrix polymer and a particle additive dispersed therein, wherein the particles have an average particle size of 0.1-1000 microns, and the polymer fiber has a spider-silk-like microstructure comprising a fiber body and spaced spindle knot structural units on the fiber body, wherein the spindle knot structural units comprise the particles, and the radial height of the spindle knot structural units is greater than the diameter of the fiber body. The preparation method of the polymer fiber of the invention does not require greatly modifying the existing spinning processes, and the equipment does not need to be changed, the process is simple, and the cost is low. The obtained spider-silk-like polymer fiber can realize the directional movement of water droplets on the surface of the fiber, thereby having a water gathering function and can be used for preparing water gathering materials.

An apparatus for producing ultrafine fibers is configured to produce ultrafine fibers by melting and drawing raw filaments. The apparatus for producing ultrafine fibers comprises: a plurality of raw filament passages arranged in a straight row; and a laser irradiation device for irradiating a plurality of raw filaments with a laser beam so as to melt, oscillate and vibrate the plurality of raw filaments after the plurality of raw filaments have passed through the respective raw filament passages together with airstreams. Specifically, the laser irradiation device is configured to output a focused laser beam having a diameter decreasing as distance from the laser irradiation device increases, and having a beam axis parallel to a direction of the row of the plurality of raw filament passages.

An apparatus for producing ultrafine fibers is configured to produce ultrafine fibers by melting and drawing raw filaments. The apparatus for producing ultrafine fibers comprises: a plurality of raw filament passages arranged in a straight row; and a laser irradiation device for irradiating a plurality of raw filaments with a laser beam so as to melt, oscillate and vibrate the plurality of raw filaments after the plurality of raw filaments have passed through the respective raw filament passages together with airstreams. Specifically, the laser irradiation device is configured to output a focused laser beam having a diameter decreasing as distance from the laser irradiation device increases, and having a beam axis parallel to a direction of the row of the plurality of raw filament passages.

An apparatus is described. The apparatus comprises a liquid dispenser comprising a liquid outlet, the liquid dispenser being configured to generate a droplet stream. The apparatus also comprises a first fluid flow device configured to generate a confinement fluid flow for confining a trajectory of the droplet stream therein, the first fluid flow device comprising an outlet arranged to allow the droplet stream to exit therefrom, wherein the fluid outlet is arranged within the confinement fluid flow device. Furthermore, the apparatus comprises a second fluid flow device configured to generate a reaction fluid flow for reacting with droplets in the droplet stream, wherein the outlet of the first fluid flow device is arranged within the second fluid flow device. A method is also described.

An apparatus is described. The apparatus comprises a liquid dispenser comprising a liquid outlet, the liquid dispenser being configured to generate a droplet stream. The apparatus also comprises a first fluid flow device configured to generate a confinement fluid flow for confining a trajectory of the droplet stream therein, the first fluid flow device comprising an outlet arranged to allow the droplet stream to exit therefrom, wherein the fluid outlet is arranged within the confinement fluid flow device. Furthermore, the apparatus comprises a second fluid flow device configured to generate a reaction fluid flow for reacting with droplets in the droplet stream, wherein the outlet of the first fluid flow device is arranged within the second fluid flow device. A method is also described.

A process, for example a continuous process, for making an oral care article of manufacture containing a fibrous composition, for example a composite structure, and more particularly to a process for making an oral care article of manufacture containing a fibrous composition, such as a soluble fibrous composition, containing soluble filaments is provided.

A unitary graphene-based continuous graphitic fiber comprising at least 90% by weight of graphene planes that are chemically bonded with one another having an inter-planar spacing from 0.3354 to 0.4 nm and an oxygen content of 0.01 to 5% by weight, wherein the graphene planes are parallel to one another and parallel to a fiber axis direction and the graphitic fiber contains no core-shell structure, have no helically arranged graphene domains, and have a porosity level less than 5% by volume. This fiber can be produced by a continuous filament of graphene oxide gel having living graphene oxide molecules or functionalized graphene chains dissolved in a fluid medium. The filament is deposited onto a supporting substrate under a molecule-aligning stress condition along the filament axis direction and then subjected to drying and heating treatments.

The present application discloses and claims a method to make a flexible ceramic fibers (Flexiramics) and polymer composites. The resulting composite has an improved mechanical strength (tensile) when compared with the Flexiramics respective the nanofibers alone. Additionally a composite has better properties than the polymer alone such as lower fire retardancy, higher thermal conductivity and lower thermal expansion. Several different polymers can be used, both thermosets and thermoplastics. Flexiramics has unique physical characteristic and the composite materials can be used for numerous industrial and laboratory applications.

The present application discloses and claims a method to make a flexible ceramic fibers (Flexiramics) and polymer composites. The resulting composite has an improved mechanical strength (tensile) when compared with the Flexiramics respective the nanofibers alone. Additionally a composite has better properties than the polymer alone such as lower fire retardancy, higher thermal conductivity and lower thermal expansion. Several different polymers can be used, both thermosets and thermoplastics. Flexiramics has unique physical characteristic and the composite materials can be used for numerous industrial and laboratory applications.