A method of preparing a structure, more particularly, a method of preparing a structure capable of ensuring a space for carrying an electrode active material by a simple method which includes an electrospinning process using a double nozzle electrospinning device and a heat treatment process.

A flexible, ignition resistant, non-electrically conductive biregional fiber is disclosed. The biregional fiber comprising an inner core region of a partially oxidized thermoplastic polymeric composition and a surrounding outer sheath region of a thermoset carbonaceous material.

A flexible, ignition resistant, non-electrically conductive biregional fiber is disclosed. The biregional fiber comprising an inner core region of a partially oxidized thermoplastic polymeric composition and a surrounding outer sheath region of a thermoset carbonaceous material.

Aspects of triboelectric fibers and methods of manufacture of the fibers are described. In one example, a method of manufacture of a fiber for generating energy using the triboelectric effect includes forming a preform tube, heating the preform tube in a furnace, feeding a wire through the preform tube and the furnace during the heating, and pulling the wire through the furnace to form a fiber. The methods described herein can be relied upon to manufacture fibers long enough for industrial-scale textile manufacturing, including for use with industrial-scale looms. In one example, forming the preform tube can include providing a polypropylene tube and wrapping the polypropylene tube with a housing layer of amorphous film, such as acrylic film. The acrylic film can be relied upon to maintain the form and integrity of the polypropylene as the wire is pulled, and the acrylic film can be easily removed after the pulling.

Aspects of triboelectric fibers and methods of manufacture of the fibers are described. In one example, a method of manufacture of a fiber for generating energy using the triboelectric effect includes forming a preform tube, heating the preform tube in a furnace, feeding a wire through the preform tube and the furnace during the heating, and pulling the wire through the furnace to form a fiber. The methods described herein can be relied upon to manufacture fibers long enough for industrial-scale textile manufacturing, including for use with industrial-scale looms. In one example, forming the preform tube can include providing a polypropylene tube and wrapping the polypropylene tube with a housing layer of amorphous film, such as acrylic film. The acrylic film can be relied upon to maintain the form and integrity of the polypropylene as the wire is pulled, and the acrylic film can be easily removed after the pulling.

A single-mode crystal fiber is provided. The fiber has a core. The core is made of a crystalline material with a melting point above 1900 degrees Celsius (° C.). The core has a coat. The coat is made of a crystalline material the same as that of the core. Through immersion plating under a low vacuum pressure and a high temperature, the material of the coat is sintered to form an outer layer covering the core. Thus, the thickness of the coat is controlled. A single crystal totally the same as that of the core is grown in a solid state with no ceramics contained. Consequently, the crystal contains no ceramics; and, through being sintered in a vacuum environment, the crystal has pores the smallest in size and the fewest in number, as compared to those sintered under a normal pressure.

A single-mode crystal fiber is provided. The fiber has a core. The core is made of a crystalline material with a melting point above 1900 degrees Celsius (° C.). The core has a coat. The coat is made of a crystalline material the same as that of the core. Through immersion plating under a low vacuum pressure and a high temperature, the material of the coat is sintered to form an outer layer covering the core. Thus, the thickness of the coat is controlled. A single crystal totally the same as that of the core is grown in a solid state with no ceramics contained. Consequently, the crystal contains no ceramics; and, through being sintered in a vacuum environment, the crystal has pores the smallest in size and the fewest in number, as compared to those sintered under a normal pressure.

Methods and a device for the continuous manufacturing of artificial muscle actuator device fibers are disclosed. The method includes: threading an untwisted fiber along the axis of a tube and inside the tube that includes a heating means to raise the localized temperature of a cross-section of the tube to a predetermined temperature; providing a tension on the untwisted fiber; and twisting the untwisted fiber while the fiber is within the tube.

Methods and a device for the continuous manufacturing of artificial muscle actuator device fibers are disclosed. The method includes: threading an untwisted fiber along the axis of a tube and inside the tube that includes a heating means to raise the localized temperature of a cross-section of the tube to a predetermined temperature; providing a tension on the untwisted fiber; and twisting the untwisted fiber while the fiber is within the tube.

A method of making a cellulose-nanoclay hemostatic nanocomposite fiber, including the steps of preparing a homogenous cellulose solution including cellulose and a room temperature ionic liquid, preparing a nanoclay suspension including halloysite and distilled water, electrospinning the cellulose solution into a first bath including the nanoclay suspension, transferring solidified cellulose-halloysite fibers from the first bath to a second bath including ethanol and distilled water, removing the solidified cellulose-halloysite fibers from the second bath, and freeze-drying the solidified cellulose-halloysite fibers.