Extruded deposition of fiber reinforced polymers

What is claimed is: 1. An end effector for performing deposition of a fiber reinforced polymer, comprising: a supply of a continuous fiber reinforcement; a supply of a flowable polymer; and a deposition head having: a material supply end configured to receive the continuous fiber reinforcement, a deposition end configured to deposit a bead of the polymer having the continuous fiber reinforcement entrained therein, a convergence region, a capillary tube extending from the convergence region to the deposition end of the deposition head, a guide tube extending from the material supply end of the deposition head to the convergence region and coaxially aligned with the capillary tube, a polymer inlet, and a polymer passageway extending from the polymer inlet to the convergence region; wherein the continuous fiber reinforcement extends from the material supply end of the deposition head through the guide tube and the convergence region and into the capillary tube and is loosely fed into the guide tube at the material supply end of the deposition head such that the continuous fiber reinforcement is not forced into the guide tube and is not placed in any substantial amount of compression at the material supply end of the deposition head; and wherein the supply of flowable polymer is connected to the polymer inlet to establish a pressurized flow of the polymer through the polymer passageway and the convergence region and into the capillary tube to draw the continuous fiber reinforcement into and through the capillary tube where the continuous fiber reinforcement becomes entrained in the polymer. 2. The end effector of claim 1 , wherein the deposition head includes: an entrainment barrel including the convergence region in which the continuous fiber reinforcement and the flowable polymer converge. 3. The end effector of claim 2 , wherein the entrainment barrel further includes an extrusion die coupled with the deposition end. 4. The end effector of claim 2 , wherein the entrainment barrel further includes the capillary tube coupled with the convergence region and configured to entrain the continuous fiber reinforcement in the polymer. 5. The end effector of claim 4 , wherein: the capillary tube includes an upstream end coupled with the convergence region and a downstream end configured to extrude the polymer having the continuous fiber reinforcement entrained therein. 6. The end effector of claim 2 , further comprising: a heater for heating the entrainment barrel, the heater including at least one heating coil having a plurality of coil turns that vary in number along a length of the entrainment barrel. 7. The end effector of claim 2 further comprising: a cutter disposed to cut the bead of the polymer. 8. The end effector of claim 7 , wherein the cutter is selected from the group consisting of: a laser, an ultrasonic knife, and a guillotine blade. 9. The end effector of claim 2 further comprising: a controller configured to control operation of the end effector. 10. The end effector of claim 2 further comprising: a manipulator attached to the deposition head and configured to manipulate the deposition head. 11. The end effector of claim 10 , wherein the manipulator rasters the end effector over a platform to deposit the bead on the platform. 12. The end effector of claim 2 further comprising: a manipulator attached to the deposition head and configured to manipulate the deposition head and to raster the end effector over a platform to deposit the bead on the platform; and a controller configured to control operation of the end effector and of the manipulator. 13. The end effector of claim 12 further comprising: a storage medium storing computer assisted design (CAD) files usable by the controller to control deposition of the bead. 14. The end effector of claim 13 , wherein the storage medium further comprises program code for converting the CAD files to stereolithography (STL) files defining surfaces of a part to be built on the platform. 15. The end effector of claim 14 , wherein the storage medium further comprises program code comprising build programs which are used to control operation of the manipulator and the controller. 16. The end effector of claim 2 further comprising a heater and a controller, and wherein: the supply of continuous fiber reinforcement has a first melt temperature; the flowable polymer has a second melt temperature that is less than the first melt temperature such that when entrainment is performed, the controller is configured to operate the heater to heat the supply of continuous fiber reinforcement and the flowable polymer to a third temperature that is above the first melt temperature but below the second melt temperature. 17. The end effector of claim 16 , wherein the deposition head comprises: the guide tube being disposed inside an annular inlet of the entrainment barrel surrounding the guide tube, wherein the guide tube ends at an entrance to the capillary tube disposed inside the entrainment barrel. 18. An end effector for performing deposition of a fiber reinforced polymer, comprising: a supply of a continuous fiber reinforcement; a supply of a flowable polymer; and a plurality of deposition heads ganged together in an array, wherein each of the plurality of deposition heads comprises: a material supply end configured to receive the continuous fiber reinforcement, a deposition end configured to deposit a bead of the polymer having the continuous fiber reinforcement entrained therein, a convergence region, a capillary tube extending from the convergence region to the deposition end of the deposition head, a guide tube extending from the material supply end of the deposition head to the convergence region and coaxially aligned with the capillary tube, a polymer inlet, and a polymer passageway extending from the polymer inlet to the convergence region, wherein the continuous fiber reinforcement extends from the material supply end of the deposition head through the guide tube and the convergence region and into the capillary tube and is loosely fed into the guide tube at the material supply end of the deposition head such that the continuous fiber reinforcement is not forced into the guide tube and is not placed in any substantial amount of compression at the material supply end of the deposition head, and wherein the supply of flowable polymer is connected to the polymer inlet to establish a pressurized flow of the polymer through the polymer passageway and the convergence region and into the capillary tube to draw the continuous fiber reinforcement into and through the capillary tube where the continuous fiber reinforcement becomes entrained in the polymer. 19. The end effector of claim 18 further comprising a heater and a controller, and wherein: each of the plurality of deposition heads comprises the guide tube, the guide tube being disposed inside an annular inlet of an entrainment barrel surrounding the guide tube; wherein the guide tube ends at an entrance to the capillary tube disposed inside the entrainment barrel. 20. A method for performing deposition of a fiber reinforced polymer, comprising: providing a continuous fiber reinforcement from a supply of the continuous fiber reinforcement and a polymer from a supply of flowable polymer to a deposition head, wherein the deposition head comprises: a material supply end configured to receive the continuous fiber reinforcement, a deposition end configured to deposit