Hotend for additive manufacturing with an actuated rod in a heated chamber

What is claimed is: 1. A hotend assembly for an additive manufacturing device, the hotend assembly comprising: a heated chamber; a number of inlets configured to feed a filament into the heated chamber; an exit orifice from a first end of the heated chamber; a bearing housing attached at a second end of the heated chamber opposite the first end; and an actuated rod extending from the bearing housing into the heated chamber, wherein the filament enters the heated chamber tangentially to the actuated rod, and wherein the actuated rod imparts mechanical energy to the filament inside the heated chamber prior to extrusion through the exit orifice. 2. The hotend assembly according to claim 1 , wherein the actuated rod is capable of distributing and disbursing constituents of the filament within the heated chamber. 3. The hotend assembly according to claim 2 , wherein the actuated rod blends two or more filaments uniformly. 4. The hotend assembly according to claim 1 , further comprising a number of filament drivers that control the flow of material from corresponding material supply units to the inlets, wherein the actuated rod assists to control axial flow of the filament through the heated chamber in coordination with the filament drivers by converting rotational energy into axial flow. 5. The hotend assembly according to claim 1 , further comprising a number of channels within the heated chamber, wherein the channels are connected to the inlets. 6. The hotend assembly according to claim 1 , further comprising a motor configured to rotate the actuated rod within the heated chamber. 7. The hotend assembly according to claim 6 , further comprising a flexible coupling that couples the motor to the actuated rod. 8. The hotend assembly of claim 1 , further comprising a number of heat sinks surrounding the inlets. 9. The hotend assembly of claim 1 , wherein the actuated rod comprises at least one of: a number of flat faces; a helical shape; or a twin-screw configuration. 10. A hotend assembly for an additive manufacturing device, the hotend assembly comprising: a heated chamber; a number of inlets configured to feed filament into the heated chamber, wherein the inlets are inserted into the heated chamber within a common plane around the heated chamber with approximately 120 degrees of separation between each inlet; an exit orifice from a first end of the heated chamber; a bearing housing attached at a second end of the heated chamber opposite the first end; an actuated rod extending from the bearing housing into the heated chamber, wherein the filament enters the heated chamber tangentially to the actuated rod, and wherein the actuated rod imparts mechanical energy to the filament inside the heated chamber prior to extrusion through the exit orifice; a motor configured to rotate the actuated rod; and a flexible coupling that couples the actuated rod to the motor, wherein the bearing housing, the exit orifice, the actuated rod, the motor, and the flexible coupling are axially aligned. 11. The hotend assembly of claim 10 , wherein the actuated rod comprises a number of flat faces. 12. The hotend assembly of claim 10 , wherein the actuated rod comprises a helix. 13. A method of additive manufacturing, the method comprising: feeding filament into a heated chamber of a hotend through a number of filament inlets, wherein the hotend is mounted to an additive manufacturing device; heating the filament with the heated chamber; rotating an actuated rod within the heated chamber to impart mechanical energy to the filament, wherein the actuated rod extends into the heated chamber from a bearing housing attached to a first end of the heated chamber, and wherein the filament enters the heated chamber tangentially to the actuated rod; and extruding the filament through the exit orifice of the hotend at a second end of the heated chamber opposite the first end. 14. The method of claim 13 , wherein the actuated rod distributes and disperses materials comprising the filament within the heated chamber. 15. The method of claim 13 , wherein rotating the actuated rod uniformly blends two or more filaments. 16. The method of claim 13 , further comprising a number of heat sinks surrounding the inlets. 17. The method of claim 13 , wherein the actuated rod comprises at least one of: a number of flat faces; a helical shape; or a twin-screw configuration. 18. The method of claim 13 , wherein the actuated rod can rotate in a clockwise or counter-clockwise direction. 19. The hotend assembly of claim 4 , wherein at least one material supplied by material supply units to the filament inlets is heterogeneous to materials supplied by the other material supply units. 20. The hotend assembly of claim 10 , further comprising a number of filament drivers that control the flow of material from corresponding material supply units to the inlets, wherein at least one material supplied by material supply units to the filament inlets is heterogeneous to materials supplied by the other material supply units.