Thermal drying system for additive manufacturing device

The invention claimed is: 1. An additive manufacturing device comprising: at least one liquefier assembly configured to receive a filament material from at least one feedstock and extrude the material in a flowable form; a thermal drying system configured to receive a stream of machine compressed air, the thermal drying system comprising: an air dryer configured to intake and remove moisture from the machine compressed air and to thereby output an airflow of dried compressed air; an air pressure regulator configured to receive the airflow of dried compressed air and to regulate a pressure of the dried compressed air to a pressure below a pressure of the received dried compressed air and above ambient air pressure and to thereby output an airflow of pressure-regulated dried compressed air; and a heater having a temperature controller configured to intake and heat the airflow of pressure-regulated dried compressed air to a preselected temperature set point based on properties of the filament material and to thereby form conditioned air; and at least one enclosed filament path configured to house and guide the filament material from a supply to the at least one liquefier assembly, wherein the enclosed filament path is configured to receive the conditioned air from the thermal drying system, to maintain a positive pressure within the enclosed filament path, and to keep the filament material from absorbing moisture as it is fed to the at least one liquefier assembly. 2. The additive manufacturing device of claim 1 , wherein the air dryer comprises one of a deliquescent, desiccant and membrane air dryer. 3. The additive manufacturing device of claim 1 , wherein the preselected temperature set point varies based on a type of filament material. 4. The additive manufacturing device of claim 1 , wherein the preselected temperature setpoint is in a range between about 125° F. and 415° F. 5. The additive manufacturing device of claim 1 , wherein the at least one liquefier assembly comprises a first liquefier assembly configured to receive a part filament material that is fed from a first feedstock through a first enclosed filament path, wherein the thermal drying system is configured to expose the conditioned air to the part filament material in the first enclosed path. 6. The additive manufacturing device of claim 5 , wherein the at least one liquefier assembly comprises a second liquefier assembly configured to receive a support filament material that is fed from a second feedstock through a second enclosed filament path, wherein the thermal drying system is configured to expose the conditioned air to the support filament material in the second enclosed path. 7. An additive manufacturing device comprising: a first consumable supply containing a part filament material; a second consumable supply containing a support filament material; a first guide tube configured to provide a first enclosed path for the part filament material from the first consumable supply to a first liquefier assembly; a second guide tube configured to provide a second enclosed path for the support filament material from the second consumable supply to a second liquefier assembly; and a thermal drying system configured to receive machine shop compressed air, reduce pressure of the compressed air, remove water vapor and heat the compressed air to a temperature set point to form conditioned air, the thermal drying system comprising: an air dryer configured to intake and remove moisture from the machine compressed air and to thereby output an airflow of dried compressed air; an air pressure regulator configured to receive the airflow of dried compressed air and to regulate a pressure of the dried compressed air to a pressure below a pressure of the received dried compressed air and above ambient air pressure and to thereby output an airflow of pressure-regulated dried compressed air; and a heater having a temperature controller configured to heat the airflow of pressure-regulated dried compressed air to a preselected temperature set point based on properties of the filament material and to thereby form conditioned air; and wherein the thermal drying system forces the conditioned air into the enclosed path of the first guide tube and the enclosed path of the second guide tube to maintain a positive pressure within the enclosed filament paths of the first guide tube and the second guide tube to keep the part filament material and the support filament material from absorbing moisture as the part filament is fed to the first liquefier assembly and the second liquefier assembly. 8. The additive manufacturing device of claim 7 , wherein the preselected temperature set point varies based on a type of the part filament material and the support filament material. 9. The additive manufacturing device of claim 7 , wherein the air dryer comprises one of a deliquescent, desiccant and membrane air dryer. 10. The additive manufacturing device of claim 7 , wherein the preselected temperature set point varies based on a type of filament material. 11. The additive manufacturing device of claim 7 , wherein the preselected temperature setpoint is in a range of between about 125° F. and 415° F. 12. A method of keeping filament material in an additive manufacturing device dry before being extruded, the method comprising: providing a machine shop source of compressed air at a first pressure; removing water vapor from the compressed air by processing the compressed air through an air dryer to output an airflow of dried compressed air; processing the outputted air flow of dried compressed air through a pressure regulator to reduce the pressure of the outputted dried compressed air to provide the dried compressed air at a second pressure that is less than the first pressure and above ambient air pressure and thereby outputing an airflow of pressure-regulated dried compressed air; heating the pressure-regulated dried compressed air at the second pressure in a heater to raise the temperature of the pressure-regulated dried compressed air to a preselected temperature set point based on properties of the filament material to form conditioned air; and introducing the conditioned air into an enclosed filament path to house and guide the filament material from a supply to a liquefier assembly, wherein the conditioned air maintains a positive pressure within the enclosed filament path such that the filament material is prevented from absorbing moisture from ambient air. 13. The method of claim 12 , wherein heating the pressure-regulated dried compressed air to a preselected temperature set point comprises varying the set temperature using a temperature controller to control the heater so that the preselected temperature set point varies depending on a type of filament material. 14. The method of claim 12 , wherein introducing the conditioned air into the enclosed filament path comprises introducing the conditioned air into an enclosed path that houses and guides the filament material from a container portion to a liquefier assembly of the additive manufacturing device. 15. The method of claim 12 , wherein introducing the conditioned air into the enclosed filament path comprises introducing the conditioned air into a first enclosed path that houses and guides a part filament material from a first container portion to a first liquefier assembly of the additive manufacturing device and introducing the conditioned air into a second enclosed path that houses and guides a support filament material from a second container portion to a second liquefier assembly of the additive manufacturi