Method And Apparatus For Controlling Heat For Improved Extrudate Flow In Three-Dimensional (3D) Printing

1 - 29 . (canceled) 30 . A method of forming a metal part via additive manufacturing, the method comprising: receiving a solid rod of feedstock within an extruder; moving the feedstock gravitationally downward through the extruder from a proximal region of the extruder towards an extrusion tip while the feedstock is oriented along a longitudinal axis of the extruder that passes through the extrusion tip; cooling the proximal region of the extruder to maintain the feedstock as the solid rod while the feedstock is within the proximal region of the extruder; and heating the extrusion tip to at least partially melt the feedstock as it passes through the extrusion tip in order to extrude the at least partially melted feedstock from the extrusion tip; and extruding the at least partially melted feedstock from the extrusion tip to form the metal part. 31 . The method of claim 30 , wherein cooling the proximal region of the extruder comprises: generating air flow within a chamber that houses at least the proximal portion of the extruder. 32 . The method of claim 31 , wherein one or more fans are used to generate the air flow within the chamber. 33 . The method of claim 31 , wherein the generated air flow is directed towards the feedstock. 34 . The method of claim 31 , wherein the generated air flow is directed towards one or more cooling fins configured to cool the generated air flow and to direct the cooled air flow towards the feedstock. 35 . The method of claim 30 , wherein cooling the feedstock comprises: liquid cooling the feedstock. 36 . The method of claim 30 , further comprising exposing the extruder to a vacuum pressure. 37 . A method of forming a metal part via additive manufacturing, the method comprising: receiving a solid rod of feedstock within an extruder, wherein the extruder includes a cooled proximal portion, a heated distal tip, and a longitudinal axis extending through a central region of the proximal portion and a central region of the distal tip; moving the feedstock through the proximal portion and towards the distal tip while the feedstock is oriented along the longitudinal axis; cooling the feedstock to maintain the feedstock as the solid rod while the feedstock is within the proximal portion so that the feedstock resists deformation while moving through the proximal portion; and heating a portion of the feedstock located within the distal tip to at least partially melt the feedstock as it passes through the distal tip in order to extrude the at least partially melted feedstock from the distal tip. 38 . The method of claim 37 , wherein cooling the feedstock includes passing a cooled liquid relative to the proximal portion of the extruder. 39 . The method of claim 37 , wherein cooling the feedstock includes exposing the proximal portion of the extruder to a heat sink. 40 . The method of claim 37 , wherein cooling the feedstock includes passing a flow of air relative to the proximal portion of the extruder. 41 . The method of claim 37 , wherein the proximal portion of the extruder is exposed to vacuum pressure. 42 . A system for forming a metal part via additive manufacturing, the system comprising: an extruder of a three-dimensional printer, the extruder having a cooled proximal portion, a heated distal tip, and a longitudinal axis extending through a central region of the proximal portion and a central region of the distal tip, wherein the extruder is configured to receive a feedstock in a solid form; a chamber housing at least the proximal portion of the extruder; a heat sink thermally coupled to the proximal portion of the extruder and configured to cool the proximal portion of the extruder; a heat block thermally coupled to the distal tip of the extruder and configured to heat the distal tip of the extruder; and a heat break located between the heat sink and the heat block, thermally separating the heat sink from the heat block. 43 . The system of claim 42 , further comprising a drive train configured to advance the feedstock through the extruder. 44 . The system of claim 42 , further comprising a controller, wherein the controller is configured to adjust an amount of heat transferred to the extruder at the distal tip. 45 . The system of claim 44 , further comprising a temperature sensor configured to sense a temperature of the extruder, wherein the temperature sensor is operably coupled to the controller. 46 . The system of claim 42 , further comprising one or more fans configured to generate air flow within the chamber. 47 . The system of claim 46 , wherein the heat sink includes a plurality of cooling fins configured to cool the air flow and direct the air flow towards the feedstock. 48 . The system of claim 42 , wherein the heat sink includes a liquid coolant. 49 . The system of claim 42 , wherein the chamber is sealed and configured to maintain a vacuum environment.