Method for processing massive fiber-composite preforms

What is claimed: 1. A method comprising: placing, in abutting relationship, plural small-diameter fiber bundles, wherein each of the small-diameter fiber bundles abuts at least one other of the small-diameter fiber bundles; heating the small-diameter fiber bundles to at least a heat deflection temperature of a resin within the small-diameter fiber bundles, but to less than a melting point of the resin; applying unification pressure to the small-diameter fiber bundles, thereby unifying the plural small-diameter fiber bundles into a single massive fiber bundle while substantially preserving a cross-sectional shape of each of the plural small-diameter fiber bundles; cooling the massive fiber bundle; and cutting the massive fiber bundle into a plurality of first portions by: (a) preheating a segment of one of the first portions of the massive fiber bundle to the heat deflection temperature; and (b) heating the preheated segment while bending the segment in a bending die, thereby forming a preform with a bend. 2. The method of claim 1 wherein a bending radius of the bending die is greater than or about equal to a diameter of the massive fiber bundle. 3. The method of claim 2 wherein a length of the preheated segment is equal to or greater than rθ (π/180), where θ is a bend angle of the segment in degrees, and r is the bending radius of the bending die. 4. The method of claim 1 wherein a length of the preheated segment is equal to or greater than rθ (π/180), where θ is a bend angle of the segment in degrees, and r is a bending radius of the bending die. 5. The method of claim 1 comprising: placing two or more of the preforms in a fixture that organizes the preforms into a geometry of a part to be formed, or a geometry of a portion of the part; heating the preforms to the heat deflection temperature of the resin in the preforms; and applying pressure to the preforms, wherein the pressure is insufficient to fully consolidate the preforms. 6. The method of claim 5 wherein the pressure applied to the preforms is less than about 100 psig. 7. The method of claim 1 wherein a diameter of the massive fiber bundle is less than a sum of the diameters of each of the small-fiber diameter bundles. 8. A method comprising: placing, in abutting relationship, plural small-diameter fiber bundles, wherein each of the small-diameter fiber bundles abuts at least one other of the small-diameter fiber bundles; heating the small-diameter fiber bundles to at least a heat deflection temperature of a resin within the small-diameter fiber bundles, but to less than a melting point of the resin; applying unification pressure to the small-diameter fiber bundles, thereby unifying the plural small-diameter fiber bundles into a single massive fiber bundle while substantially preserving a cross-sectional shape of each of the plural small-diameter fiber bundles; cooling the massive fiber bundle; cutting the massive fiber bundle into a plurality of first portions; placing two or more of the first portions in a fixture that organizes the first portions into a geometry of a part to be formed, or a geometry of a portion of the part; heating the first portions to the heat deflection temperature of the resin in the first portions; and applying pressure to the first portions, wherein the pressure is insufficient to fully consolidate the first portions. 9. The method of claim 8 wherein the pressure applied to the first portions is less than about 100 psig. 10. The method of claim 8 wherein a diameter of the massive fiber bundle is less than a sum of the diameters of each of the small-fiber diameter bundles. 11. A method comprising: placing, in abutting relationship, plural small-diameter fiber bundles, wherein each of the small-diameter fiber bundles abuts at least one other of the small-diameter fiber bundles; heating the small-diameter fiber bundles to at least a heat deflection temperature of a resin within the small-diameter fiber bundles, but to less than a melting point of the resin; applying unification pressure to the small-diameter fiber bundles, thereby unifying the plural small-diameter fiber bundles into a single massive fiber bundle while substantially preserving a cross-sectional shape of each of the plural small-diameter fiber bundles; cooling the massive fiber bundle; and crimping the massive fiber bundle at intervals enabling the massive fiber bundle to be folded back and forth onto itself. 12. The method of claim 11 comprising cutting the crimped massive fiber bundle, resulting in a plurality of first portions of the massive fiber bundle. 13. The method of claim 12 comprising: preheating a segment of one of the first portions of the massive fiber bundle to the heat deflection temperature; and heating the preheated segment while bending the segment in a bending die, thereby forming a preform with a bend. 14. The method of claim 13 wherein a bending radius of the bending die is greater than or about equal to a diameter of the massive fiber bundle. 15. The method of claim 14 wherein a length of the preheated segment is equal to or greater than rθ (π/180), where θ is a bend angle of the segment in degrees, and r is the bending radius of the bending die. 16. The method of claim 13 wherein a length of the preheated segment is equal to or greater than rθ (π/180), where θ is a bend angle of the segment in degrees, and r is a bending radius of the bending die. 17. The method of claim 11 wherein a diameter of the massive fiber bundle is less than a sum of the diameters of each of the small-fiber diameter bundles. 18. A method comprising: placing, in abutting relationship, plural small-diameter fiber bundles, wherein each of the small-diameter fiber bundles abuts at least one other of the small-diameter fiber bundles; heating the small-diameter fiber bundles to at least a heat deflection temperature of a resin within the small-diameter fiber bundles, but to less than a melting point of the resin; applying unification pressure to the small-diameter fiber bundles, thereby unifying the plural small-diameter fiber bundles into a single massive fiber bundle while substantially preserving a cross-sectional shape of each of the plural small-diameter fiber bundles; bending and cutting the massive fiber bundle to form a plurality of preforms, at least some of which preforms include at least one bend; and cooling the plurality of preforms. 19. The method of claim 18 wherein a diameter of the massive fiber bundle is less than a sum of the diameters of each of the small-fiber diameter bundles.