A metal carbide ceramic fiber having improved mechanical properties and characteristics and improved processes and chemical routes for manufacturing metal carbide ceramic fiber. Metal carbide ceramic fibers may be formed via reaction bonding of a metal-based material (e.g. boron) with the inherent c
A metal carbide ceramic fiber having improved mechanical properties and characteristics and improved processes and chemical routes for manufacturing metal carbide ceramic fiber. Metal carbide ceramic fibers may be formed via reaction bonding of a metal-based material (e.g. boron) with the inherent carbon of a carrier medium. One embodiment includes a method of making a metal carbide ceramic fiber using VSSP to produce high yield boron carbide fiber. Embodiments of the improved method allow high volume production of high density boron carbide fiber. The chemical routes may include a direct production of boron carbide fiber from boron carbide powder (B4C) and precursor (e.g. rayon fiber) having a carbon component to form a B4C/rayon fiber that may be processed at high temperature to form boron carbide fiber, and that may be subsequently undergo a hot isostatic pressing to improve fiber purity. Another route may include a carbothermal method comprising combining boron powder (B) with a precursor (e.g., rayon fiber) having a carbon component to form a B/rayon fiber, carbonizing and a chemical reaction of boron (B) and carbon (C) to form boron carbide fiber. Another carbothermal method may comprise combining boron oxide powder (B2O3) with a precursor (e.g., rayon fiber) having a carbon component to form a B2O3/rayon fiber, carbonizing and a chemical reaction of boron oxide (B2O3) and carbon (C) to form boron carbide (B4C) fiber.
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1. A direct method for manufacturing boron carbide ceramic fiber from boron carbide, consisting of: digesting cellulose in an aqueous solution of sodium hydroxide and disulfide to form a viscose;dispersing a metal-based material in the cellulose based viscose to form a boron carbide loaded slurry, t
1. A direct method for manufacturing boron carbide ceramic fiber from boron carbide, consisting of: digesting cellulose in an aqueous solution of sodium hydroxide and disulfide to form a viscose;dispersing a metal-based material in the cellulose based viscose to form a boron carbide loaded slurry, the metal-based material comprising boron carbide (B4C);spinning the boron carbide loaded slurry to form a green fiber, the green fiber comprising a matrix of cellulose with the boron carbide dispersed therein, wherein in one step the green fiber and the cellulose matrix are formed, the cellulose acting as a binder in the fiber forming process;heat treating the boron carbide loaded cellulose matrix of the green fiber to a low temperature to produce excess carbon as a sintering aid, wherein via sintering the boron carbide fuses together as the temperature increases to a high temperature to form boron carbide ceramic fiber, and wherein the reaction forming boron carbide (B4C) ceramic fiber is defined as: B4C+C→B4C. 2. The method of claim 1, wherein the first portion is at least about 90% of the cellulose. 3. The method of claim 1, wherein the heat treating occurs in a single step in a furnace under a controlled atmosphere, wherein the temperature increases from a low temperature of about 500° C. to a high temperature of about 1,800° C. to about 2,300° C. 4. The method of claim 1, wherein: the spinning further comprises pumping the slurry through a plurality of holes in a spinneret into a bath of warm, mild sulfuric acid with a high concentration of salt; andfurther comprising an acid/base reaction that coagulates the cellulose into rayon green fiber with a high volume percentage of the metal-based material uniformly dispersed therein. 5. The method of claim 1, further comprising yielding high production volume of boron carbide ceramic fiber, high production volume yields comprising producing boron carbide ceramic fiber at a rate of at least about 5 m/min using a single spinneret. 6. The method of claim 1, further comprising producing fibers having a cross-sectional diameter in the range of from about 5 μm down to about 1 μm. 7. The method of claim 1, further comprising sintering at a high temperature the boron carbide ceramic fiber through use of the excess carbon in amounts sufficient for providing a sintering aid to improve the density and hardness thereof, and help reduce sintering temperature. 8. A direct method for manufacturing boron carbide ceramic fiber from boron carbide, consisting of: digesting cellulose in an aqueous solution of sodium hydroxide and disulfide to form a viscose;dispersing alumina (Al2O3) in the cellulose based viscose to form a boron carbide and alumina loaded slurry; andspinning the boron carbide and alumina loaded slurry to form a green fiber, the green fiber comprising a cellulose matrix with the boron carbide and alumina dispersed therein, wherein in one step the green fiber and the cellulose matrix are formed, the cellulose acting as a binder in the fiber forming process;heat treating the boron carbide loaded cellulose matrix of the green fiber to a low temperature to produce excess carbon as a sintering aid, wherein via sintering the boron carbide fuses together as the temperature increases to a high temperature to form boron carbide ceramic fiber,and using the alumina as a sintering aid during the heat treating of the green fiber to form the boron carbide ceramic fiber, the reaction forming boron carbide (B4C) ceramic fiber defined as: B4C +C+Al2O3→B4C. 9. A direct method for manufacturing boron carbide ceramic fiber from boron carbide, consisting of: digesting cellulose in an aqueous solution of sodium hydroxide and disulfide to form a viscose;dispersing a metal-based material in the cellulose based viscose to form a boron carbide loaded slurry, the metal-based material comprising boron carbide (B4C);spinning the boron carbide loaded slurry to form a green fiber, the green fiber comprising a matrix of cellulose with the boron carbide dispersed therein, wherein in one step the green fiber and the cellulose matrix are formed, the cellulose acting as a binder in the fiber forming process;heat treating the boron carbide loaded cellulose matrix of the green fiber to a low temperature to produce carbon as a sintering aid, wherein the boron carbide fuses together as the temperature increases to a high temperature to form boron carbide ceramic fiber, and wherein the reaction forming boron carbide (B.C) ceramic fiber is defined as: B4C+C→B4C1, and pressureless sintering of the boron carbide ceramic fiber to further densify and harden the metal carbide ceramic fiberand hot pressing (Post- HlPing) the boron carbide ceramic fiber to further improve the density and hardness of the metal carbide fiber producing a full density boron carbide ceramic fiber. 10. A direct method for manufacturing boron carbide ceramic fiber from boron carbide, consisting of: digesting cellulose in an aqueous solution of sodium hydroxide and disulfide to form a viscose;dispersing a metal-based material in the cellulose based viscose to form a boron carbide loaded slurry, the metal-based material comprising boron carbide (B4C);spinning the boron carbide loaded slurry to form a green fiber, the green fiber comprising a matrix of cellulose with the boron carbide dispersed therein, wherein in one step the green fiber and the cellulose matrix are formed, the cellulose acting as a binder in the fiber forming process;heat treating the boron carbide loaded cellulose matrix of the green fiber to a low temperature to produce carbon as a sintering aid, wherein the boron carbide fuses together as the temperature increases to a high temperature to form boron carbide ceramic fiber, and wherein the reaction forming boron carbide (B.C) ceramic fiber is defined as: B4C+C→B4C1, and forming a composite incorporating the boron carbide fibers, wherein the composite further comprises a three dimensional woven composite.
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이 특허에 인용된 특허 (13)
Masanobu Kobayashi JP; Mitsutoshi Ozaki JP; Youji Matsuhisa JP, Carbon fibers and process for the production thereof.
Patel Kundan M. (Randolph NJ) Mares Frank (Whippany NJ) Mackey Joseph E. (E. Hanover NJ) Hatami Richard S. (Wheeling IL), Process for preparation of metal carbide fibers.
Economy James (Eggertsville NY) Lin Ruey Y. (Williamsville NY) Smith William D. (Tonawanda NY), Production of high strength carbide fibers by heat treatment.
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