Reinforced fused-deposition modeling

1 - 35 . (canceled) 36 . A method for forming a three-dimensional object, comprising: (a) directing a first fiber from a first spool and a second fiber from a second spool to an opening, wherein said first fiber comprises a thermoplastic material; (b) upon directing said first fiber and said second fiber to said opening, using a heater to subject said first fiber to heating to generate a plurality of beads comprising said thermoplastic material; and (c) sequentially providing individual beads of said plurality of beads adjacent to a platform in accordance with a computer design of said three-dimensional object, which plurality of beads adjacent to said platform is reinforced by said second fiber, thereby forming said three-dimensional object. 37 . The method of claim 36 , wherein each of said plurality of beads comprises a material included in said second fiber. 38 . The method of claim 36 , wherein said individual beads include strands of said first or second fiber that have a maximum length that is less than twice a minimum dimension of said individual beads. 39 . The method of claim 36 , wherein said individual beads include strands formed of one or more materials selected from the group consisting of glass, carbon, aramid, cotton, and wool. 40 . The method of claim 36 , wherein said thermoplastic material is part of a thermoplastic filament. 41 . The method of claim 40 , wherein said thermoplastic filament comprises a tow of fiber strands, a yarn of fiber strands, a braid of fiber strands, or a bundle of fiber strands. 42 . The method of claim 36 , wherein said individual beads include strands from said second fiber, which strands do not include said thermoplastic material. 43 . The method of claim 36 , wherein said individual beads include strands from said second fiber, which strands include said thermoplastic material. 44 . The method of claim 36 , wherein said individual beads include strands of different length, different material, or different modulus. 45 . The method of claim 36 , wherein said individual beads include different bundles of fiber strands from said first fiber or second fiber. 46 . The method of claim 36 , wherein (c) comprises combining fiber strands from said second fiber with said thermoplastic material. 47 . The method of claim 36 , wherein said computer design comprises a model said three-dimensional object and structural properties of said three-dimensional object. 48 . The method of claim 36 , wherein said platform comprises a drive mechanism for moving said platform. 49 . The method of claim 36 , wherein said platform is a turntable. 50 . The method of claim 36 , wherein (c) comprises using a positioning assembly to provide said individual beads of said plurality of beads adjacent to said platform. 51 . The method of claim 50 , wherein said positioning assembly comprises a robot arm. 52 . The method of claim 40 , wherein said opening is part of a nozzle, and wherein (c) comprises sequentially providing said individual beads of said plurality of beads through said nozzle. 53 . The method of claim 40 , wherein said second fiber comprises one or more strands, which one or more strands are directed to said opening and associated with said plurality of beads. 54 . The method of claim 40 , wherein said second fiber comprises carbon. 55 . A system for forming a three-dimensional object, comprising: a first spool comprising a first fiber, wherein said first fiber comprises a thermoplastic material; a second spool comprising a second fiber; a heater configured to subject said first fiber to heating to generate a plurality of beads comprising said thermoplastic material; a platform adjacent to which said three-dimensional object is formed; and a controller operatively coupled to said heater, wherein said controller (i) directs said first fiber from said first spool and said second fiber from said second spool to an opening, (ii) uses said heater to subject said first fiber of heating to generate a plurality of beads, and (iii) sequentially provides individual beads of said plurality of beads adjacent to said platform in accordance with a computer design of said three-dimensional object, which plurality of beads adjacent to said platform is reinforced by said second fiber, thereby forming said three-dimensional object. 56 . The system of claim 55 , wherein said computer design comprises a model said three-dimensional object and structural properties of said three-dimensional object. 57 . The system of claim 55 , wherein said platform comprises a drive mechanism for moving said platform. 58 . The system of claim 55 , further comprising a positioning assembly that provides said individual beads of said plurality of beads adjacent to said platform. 59 . The system of claim 58 , wherein said positioning assembly comprises a robot arm. 60 . The system of claim 58 , wherein said positioning assembly operates along six or seven axes. 61 . The system of claim 58 , wherein said positioning assembly is capable of depositing a bead of fiber-reinforced thermoplastic material in a helix. 62 . The system of claim 55 , wherein said opening is part of a nozzle, and wherein said controller sequentially provides said individual beads of said plurality of beads through said nozzle. 63 . The system of claim 55 , wherein said second fiber comprises one or more strands, which one or more strands are directed to said opening and associated with said plurality of beads. 64 . The system of claim 55 , wherein said controller controls a rate at which said first fiber and said second fiber are directed to said opening. 65 . The system of claim 55 , wherein said second fiber comprises carbon.