2-stage extrusion apparatus and method of extrusion

What is claimed is: 1. An apparatus configured to extrude a polymer that comprises reinforcement fibers, such that the apparatus comprises: a barrel configured to receive granulate particles of a polymer, such that the granulate particles comprise fibers that comprise a variety of lengths, such that the barrel comprises: a low compression first stage that comprises a low compression screw configured to mix and compress, in low compression, the granulate particles, such that the low compression screw comprises: a discontinuous section that comprises T-shaped blades and a helical blade that comprises cutouts configured to aid recirculation of the polymer in the low compression first stage and increase a mixture of the fibers and components in the granulate particles; and a reduced diameter section, in a transition section of the barrel that connects the low compression first stage to a high compression second stage that comprises a continuous section helical blade, such that the high compression second stage comprises a high compression screw directly connected to the low compression screw and configured to compress and extrude, under a pressure greater than a pressure in the low compression first stage, the melted polymer, such that the longest of the variety of lengths of the fibers align longitudinally with a length of the high compression screw; a heating system configured to heat and convert the granulate particles into a melted polymer; and an extrusion nozzle coupled directly the high compression second stage, such that the extrusion nozzle comprises a nozzle die that comprises a backside that comprises a circular opening concentric with the high compression screw and configured for extrusion of the melted polymer therethrough to an opening, tapered from the circular opening to a shape desired for a bead of the polymer, in a face of the nozzle die. 2. The apparatus of claim 1 , further comprising: the barrel comprises a tapered transition section; and the low compression screw extends through the transition section and comprises a varying diameter. 3. The apparatus of claim 1 , further comprising: a portion of the heating system configured to surround a portion of the transition section and convert the granulate particles of the polymer into the melted polymer. 4. The apparatus of claim 3 , further comprising the transition section of the barrel comprising a gap, between an outer edge of the helical blade of the low compression screw and an inside wall of the barrel, configured to allow recirculation, toward an aft end of the barrel, of some of the melted polymer within the transition section while a remaining portion of the melted polymer continues a flow toward the extrusion nozzle. 5. The apparatus of claim 3 , wherein the heating system comprises: a first heating jacket that surrounds a portion of the transition section, and a second heating jacket that surrounds a portion of the high compression second stage. 6. The apparatus of claim 5 , wherein: the first heating jacket comprises a heating jacket, and the second heating jacket comprises a cover that surrounds a plurality of circumferentially spaced heater rods along the high compression second stage. 7. The apparatus of claim 1 , wherein the low compression screw and the high compression screw are coupled together end-to-end. 8. The apparatus of claim 1 , wherein: the low compression screw comprises a first pitch and a first diameter; and the high compression screw comprises a second pitch and a second diameter, each respectively less than the first pitch and the first diameter. 9. The apparatus of claim 1 , wherein the cutouts extend circumferentially and form individual blade segments configured to allow recirculation, back toward the aft of the barrel, of the melted polymer within the low compression first stage. 10. Apparatus of claim 1 , further comprising: an adjustable gate configured to move over the extrusion nozzle and adjust a cross-sectional shape of the melted polymer extruded from the extrusion nozzle. 11. A robotic end effector configured to extrude a bead of a composite material that comprises a fiber reinforcement, such that the robotic end effector comprises: a barrel configured to attach to a robotic manipulator, such that the barrel comprises: a front end configured to extrude composite material therethrough; and an aft end configured to receive a granulate, of the composite material, that comprises fibers that comprise a variety of lengths; a vacuum system coupled with the barrel and configured to degas the composite material; a heating system configured to heat the granulate composite material into a melted composite material and controlled based upon a signal from a pressure sensor on a nozzle die connected to the barrel; a screw device comprising a continuous section and a discontinuous section that comprises: T-shaped blades; a reduced diameter section, and a helical blade comprising a reduced diameter section and cutouts that create individual blades from the helical blade, configured to: rotate inside the barrel; and move the composite material from the aft end to the front end of the barrel, such that a gap lies between an edge of the screw device and at least a section of an inside of the barrel such that a portion of the melted composite material recirculates back toward the aft end of the barrel as the screw drive moves a remaining portion of the melted composite material to the front end of the barrel, such that fibers of shorter length in the variety of lengths of fibers distribute randomly throughout the melted composite material; a drive configured to rotate the screw device; an extrusion nozzle, located at the front end of the barrel, that comprises: a circular opening, concentric with high compression screw, on a back sided of the nozzle die, configure to taper to a shape of an opening on a face of the nozzle die; and a gate configured to translate substantially normal to a flow of the melted composite material and vary a shape and an area of the melted composite material extruded from the barrel through the circular opening; and a laser profile sensor configured to guide the extrusion nozzle along and deliver the melted composite material into a channel such that a longest fiber, in the variety of lengths of fibers, comprises a length oriented substantially parallel to a length of the channel and the fibers of shorter length remain randomly distributed throughout the melted composite material. 12. The robotic end effector of claim 11 , further comprising the screw device comprising: a low compression screw that comprises the discontinuous section configured to mix the granulate composite material; and a high compression screw configured to consolidate the melted composite material and align longest fibers, among the variety of lengths of fibers, substantially parallel to a length of the high compression screw. 13. The robotic end effector of claim 12 , further comprising the low compression screw coupled with the drive and with the high compression screw, the low compression screw being configured to mix and feed the granulate composite material to the high compression screw. 14. The robotic end effector of claim 12 , further comprising at least a portion, located within a transition section of the barrel, of the screw device comprising a circumference spaced radially inwardly from the barrel to define a gap configured to allow the portion of the melted composite material to recirculate back toward the aft end of the barrel. 15. The robotic end effector of claim 12 , further comprising