Three dimensional printing

What is claimed is: 1. A three dimensional printer for additive manufacturing of a part, comprising: a build platen for receiving and supporting the part; a print head opposing the build platen, the print head including a conduit nozzle having an ironing outlet lip and a heater; a motorized feeding mechanism constructed and arranged to drive a composite filament toward the ironing outlet lip, wherein the composite filament includes a matrix material permeating a core of at least one axial strand extending within the filament; a motorized three axis translation mechanism constructed and arranged to translate the conduit nozzle and a build platen with respect to one another; a controller operatively connected to the heater, the feeding mechanism and the three axis translation mechanism, the controller controlling the velocity of the print head, an unattached terminal end of the composite filament, and the build platen to iron melted matrix material including the at least one axial strand by: heating the ironing outlet lip; and ironing an initial rounded cross-sectional shape of the composite filament with the at least one axial strand therein into a substantially compressed, wider than tall, second cross-sectional shape with strands redistributed therein, thereby moving the at least one axial strand to vertically compress and horizontally spread. 2. The three dimensional printer of claim 1 , further comprising a motorized cutter operatively connected to the controller and positioned between the ironing outlet lip and the feeding mechanism, wherein the matrix material comprises a thermoplastic resin, and wherein the controller further controls the cutter to sever the filament at a location where a temperature of the matrix material is less than a melting temperature of the matrix material. 3. The three dimensional printer of claim 2 , wherein the motorized cutter is positioned at or adjacent at least one of the receiving tube and the conduit nozzle outlet to cut the core reinforced filament at or adjacent at least one of the receiving tube and the conduit nozzle outlet. 4. The three dimensional printer of claim 1 , further comprising a receiving tube leading to the conduit nozzle, having a clearance fit path that prevents buckling of the core reinforced filament, and positioned between the ironing outlet lip and the feeding mechanism, wherein the controller further controls the feeding mechanism to drive the filament into the receiving tube. 5. The three dimensional printer of claim 4 , wherein the receiving tube forms a portion of a cold feed zone having a temperature lower than a melting temperature of the matrix material. 6. The three dimensional printer of claim 1 , wherein a cavity channel having a larger inner diameter than the clearance fit path is arranged between the ironing outlet lip and the feeding mechanism, and wherein the filament substantially rigidly extends from the clearance fit path into the cavity channel of the eyelet such that at least some portion of the matrix material of the filament does not contact a side wall of the cavity. 7. The three dimensional printer of claim 6 , wherein the controller further controls the velocity of the print head, the unattached terminal end of the composite filament, and the build platen to drive the filament extending substantially rigidly from the clearance fit path past the cavity channel to contact the unattached terminal end of the filament to the part, and to displace the filament towards the ironing outlet lip by translating the conduit nozzle and the part with respect to one another while the terminal end of the filament is anchored to the part. 8. The three dimensional printer of claim 6 , wherein the controller further controls the velocity of the print head, the unattached terminal end of the composite filament, and the build platen to buckle the filament, and wherein the unattached terminal end of the driven filament remains at least partially unmelted until it contacts the ironing outlet lip. 9. The three dimensional printer of claim 1 , wherein the controller further controls the velocity of the print head, the unattached terminal end of the composite filament, and the build platen to iron the melted matrix material including the at least one axial strand in a first direction in a first portion of a part and in a second direction in a second portion of the part. 10. The three dimensional printer of claim 1 , wherein the at least one axial strand within the filament includes, in any cross sectional area, a plurality of individual strands within the filament. 11. The three dimensional printer of claim 1 , wherein the ironing outlet lip is rounded, and wherein the controller further controls the velocity of the print head, the unattached terminal end of the composite filament, and the build platen to pull the core reinforced filament through the rounded ironing outlet of the conduit nozzle as the filament leaves the print head. 12. The three dimensional printer of claim 1 , wherein the controller further controls the velocity of the print head, the unattached terminal end of the composite filament, and the build platen to apply a compaction force to the filament with a rounded portion of the rounded ironing outlet lip as the filament is being deposited. 13. The three dimensional printer of claim 1 , the motorized feeding mechanism further comprising a slipping mechanism, wherein the controller further controls the motorized three axis translation mechanism velocity with respect to the feeding mechanism velocity to maintain a tension along the at least one axial strand greater than a force threshold of the slipping mechanism. 14. The three dimensional printer of claim 1 , wherein an individual strand length of the at least one axial strand extending within the filament is equal to or longer than twice the length of a melt zone of the conduit nozzle. 15. The three dimensional printer of claim 1 , wherein the controller further controls the velocity of the print head, the unattached terminal end of the composite filament, and the build platen to tension the filament in the conduit nozzle from a connection to a first portion of the part, translate the conduit nozzle through an open gap, bridge the filament across the open gap; and iron the filament to reconnect the filament to a second portion of the part. 16. The three dimensional printer of claim 1 , wherein the controller further controls the velocity of the print head, the unattached terminal end of the composite filament, and the build platen to maintain a clearance between the ironing outlet lip and a top of the part to be less than a diameter of the filament. 17. The three dimensional printer of claim 1 , wherein the controller further controls the velocity of the print head, the unattached terminal end of the composite filament, and the build platen to: apply a compression pressure directly with the ironing outlet lip to force the core reinforced filament having the initial rounded cross-sectional shape to compress into an underlying part and form the second cross-sectional compacted shape having the at least one axial strand in a changed position therein, and maintain a substantially matched velocity of the at least one axial strand and matrix material throughout the conduit nozzle, the linear feed rate of core reinforced filament having the initial shape being substantially the same as the linear deposition rate of the second compacted shape. 18. The three dimensional printer of claim 1 , further comprising: a cutting mechanism constructed and ar