Multi-beam coaxial laser optical system for use in additive manufacturing

What is claimed: 1 . An apparatus for use in laser additive manufacturing, comprising: (a) an optical housing configured to receive a laser beam therein and a feedstock therein, wherein the feedstock is configured for use in an additive manufacturing process that includes a build plate or other work surface; (b) a first reflective optic in the optical housing for receiving and reflecting the laser beam; (c) a second reflective optic in the optical housing for receiving the laser beam reflected by the first reflective optic, wherein the second reflective optic includes: (i) a first region of curvature configured to direct a portion of the laser beam received from the first reflective optic onto the feedstock in a cylindrical configuration such that the feedstock and the cylinder of laser beam are coaxial with regard to the other; and (ii) a second region of curvature distinct from the first region of curvature, wherein the second region of curvature is configured to direct a portion of the laser beam received from the first reflective optic onto the build plate or other work surface only in a ring-shaped configuration, and wherein the ring of laser beam surrounds both the feedstock and the cylinder of laser beam on the feedstock and is coaxial therewith; (d) a nozzle connected to the optical housing, wherein the nozzle includes a tapered nozzle chamber formed centrally and longitudinally therein, wherein the tapered nozzle chamber includes a first tapered chamber portion and a second tapered chamber portion, wherein the tapered nozzle chamber further includes a distinct constricted, converging-diverging portion formed within the tapered nozzle chamber and located entirely between the first and second tapered chamber portions, and wherein the distinct constricted, converging-diverging portion further forms a pressurized gas flow velocity increasing, annular aerodynamic window that provides shielding at the build plate or other work surface, thereby preventing contaminants generated during the additive manufacturing process from entering the optical housing and damaging the first and second reflective optics; and (e) a feedstock steering device disposed at least partially within the constricted, converging-diverging portion of the tapered nozzle chamber, wherein the feedstock steering device includes a ball type joint that is operative to position the feedstock coaxial with the laser beam and perpendicular to the build plane or other work surface. 2 . The apparatus of claim 1 , further comprising a shielded conduit positioned within the optical housing at a predetermined angle, wherein the shielded conduit is configured to receive the feedstock therein. 3 . The apparatus of claim 1 , further comprising at least one gas inlet formed in the optical housing, wherein the gas inlet is configured to receive the pressurized gas therethrough. 4 . The apparatus of claim 1 , further comprising a plate for supporting the first reflective optic, wherein the plate is configured to provide cooling water to an interior of the optical housing, and wherein the plate includes a plurality of spokes formed therein for allowing reflected laser beams to pass therethrough. 5 . The apparatus of claim 1 , wherein the first reflective optic is either a conical mirror or a toroidal mirror. 6 . The apparatus of claim 1 , wherein the second reflective optic is a toroidal mirror. 7 . An apparatus for use in laser additive manufacturing, comprising: (a) an optical housing, wherein the optical housing includes: (i) an upper portion, wherein the upper portion is configured to receive a laser, and wherein the laser directs a laser beam into and through the optical housing; (ii) a middle portion connected to the upper portion; and (iii) a lower portion connected to the middle portion; (b) a conduit disposed within the optical housing at a predetermined angle, wherein the conduit passes through the upper, middle, and lower portions of the optical housing; (c) a feedstock disposed within the conduit, wherein the feedstock is configured for use in an additive manufacturing process that includes a build plate or other work surface; (d) a nozzle connected to the lower portion of the optical housing for receiving the feedstock from the conduit, wherein the nozzle includes a tapered nozzle chamber formed centrally and longitudinally therein, wherein the tapered nozzle chamber includes a first tapered chamber portion and a second tapered chamber portion, wherein the tapered nozzle chamber further includes a distinct constricted, converging-diverging portion formed within the tapered nozzle chamber and located entirely between the first and second tapered chamber portions, and wherein the distinct constricted, converging-diverging portion further forms a pressurized gas flow velocity increasing, annular aerodynamic window that provides shielding at the build plate or other work surface, thereby preventing contaminants generated during the additive manufacturing process from entering the optical housing and damaging the first and second reflective optics; (e) an alignment mechanism disposed at least partially within the distinct constricted, converging-diverging portion of the nozzle, wherein the alignment mechanism includes a ball type joint that reorients the feedstock exiting the lower portion of the optical housing into a position coaxial with the laser beam and perpendicular to the build plate or other work surface; (f) a first reflective optic disposed within the middle portion of the optical housing for receiving and reflecting the laser beam; and (g) a second reflective optic disposed within the middle portion of the optical housing for receiving the laser beam reflected by the first reflective optic, wherein the second reflective optic includes: (i) a first region of curvature configured to direct a portion of the laser beam received from the first reflective optic onto the feedstock in a cylindrical configuration such that the feedstock and the cylinder of laser beam are coaxial with regard to one another; and (ii) a second region of curvature distinct from the first region of curvature, wherein the second region of curvature is configured to direct a portion of the laser beam received form the first reflective optic onto the build plate or other work surface only in a ring-shaped configuration, and wherein the ring of laser beam surrounds both the feedstock and the cylinder of laser beam on the feedstock and is coaxial therewith. 8 . The apparatus of claim 7 , further comprising at least one gas inlet formed in the optical housing, wherein the gas inlet is configured to receive the pressurized gas therethrough. 9 . The apparatus of claim 7 , further comprising at least one water inlet and at least one water exit for allowing cooling water to flow into and through the optical housing for cooling the first reflective optic. 10 . The apparatus of claim 8 , further comprising a plate for supporting the first reflective optic, wherein the plate is configured to provide cooling water to an interior of the optical housing, and wherein the plate includes a plurality of spokes formed therein for allowing reflected laser beams to pass therethrough. 11 . The apparatus of claim 7 , wherein the conduit is shielded, wherein an outer diameter of the conduit is reflective, or wherein the conduit is water-cooled. 12 . The apparatus of claim 7 , wherein the first reflective optic is either a conical mirror or a toroidal mirror. 13 . The apparatus of claim 7 , wherein the second reflective optic is a toroidal mirror. 14 . An apparatus for use in laser ad