Print assembly for additive manufacturing system, and methods of use thereof

The invention claimed is: 1. A print assembly for use in an additive manufacturing system to print three-dimensional parts, the print assembly comprising: a coarse gantry; a fine gantry operably mounted to the coarse gantry such that the coarse gantry is configured to move the fine gantry, and wherein the fine gantry has a higher fundamental resonance frequency than the coarse gantry; and a liquefier assembly configured to heat an extrudable material to a molten state and extrude the molten material, wherein at least a portion of the liquefier assembly is operably mounted to the fine gantry; wherein the fine gantry executes toolpaths with the portion of the liquefier assembly at least at 30 gees without significant toolpath errors. 2. The print assembly of claim 1 , wherein the fine gantry executes toolpaths with the portion of the liquefier assembly at least at 40 gees without significant toolpath errors. 3. The print assembly of claim 1 , wherein the fine gantry executes toolpaths with the portion of the liquefier assembly at least at 50 gees without significant toolpath errors. 4. The print assembly of claim 1 , wherein the portion of the liquefier assembly that is operably mounted to the fine gantry has a mass of less than 50 grams. 5. The print assembly of claim 1 , wherein the portion of the liquefier assembly that is operably mounted to the fine gantry comprises: an accumulator; a nozzle at an outlet end of the accumulator; and an actuator mechanism configured to controllably apply pressure to transversely compress the accumulator. 6. The print assembly of claim 5 , wherein the liquefier assembly further comprises: a drive mechanism; a liquefier configured to receive a consumable material from the drive mechanism; and one or more first heater assemblies configured to heat the liquefier for heating the received consumable material to a molten state. 7. The print assembly of claim 6 , wherein the liquefier assembly further comprises a conduit configured to receive the molten consumable material from the liquefier. 8. The print assembly of claim 1 , wherein the fine gantry comprises one or more voice coil actuators or one or more piezoelectric actuators. 9. The print assembly of claim 1 , wherein the fine gantry moves in a x-y plane. 10. The print assembly of claim 1 , wherein the fine gantry moves in along x, y and z axes. 11. The print assembly of claim 1 , wherein the fine gantry moves in a polar coordinate system. 12. The print assembly of claim 1 , wherein the fine gantry moves in a x-y plane along with rotational movement. 13. The print assembly of claim 1 , wherein the coarse gantry is configured to move in a plane. 14. The print assembly of claim 1 , wherein the coarse gantry is configured to move in five axes of motion. 15. A method of printing a 3D part with an extrusion-based additive manufacturing system, the method comprising: providing a print assembly having a fine gantry carried by a coarse gantry, the fine gantry having a higher fundamental resonance relative to the course gantry and wherein the fine gantry carries at least a portion of a liquefier with an extrusion nozzle, wherein the at least a portion of the liquefier assembly that is operably mounted to the fine gantry has a mass of less than 50 grams; extruding a molten material through the extrusion nozzle while navigating the coarse gantry along a first portion of a toolpath; and extruding the molten material through the extrusion nozzle while navigating the fine gantry along a second portion of the toolpath wherein the fine gantry executes the second portion of the toolpath with the portion of the liquefier assembly at least at 30 gees without significant toolpath errors. 16. The method of claim 15 , wherein the fine gantry executes the second portion of the toolpath at least at 40 gees without significant toolpath errors. 17. The method of claim 15 , wherein the fine executes the second portion of the toolpath at least at 50 gees without significant toolpath errors. 18. The method of claim 15 , wherein navigating the second portion of the toolpath comprises moving the fine gantry within one square inch of travel. 19. The method of claim 15 , wherein navigating the fine gantry along the second portion of the tool path comprises motion in a x-y plane. 20. The method of claim 15 , wherein navigating the fine gantry along the second portion of the tool path comprises motion in along a x, y and z axes. 21. The method of claim 15 , wherein navigating the fine gantry along the second portion of the tool path comprises motion utilizing polar coordinates. 22. The method of claim 15 , wherein navigating the fine gantry along the second portion of the tool path comprises motion in a x-y plane along with rotational movement. 23. The method of claim 15 , wherein the at least the portion of the liquefier comprises an accumulator in fluid communication with the extrusion nozzle and an actuator, the method comprising compressing or releasing pressure on the accumulator with the actuator to adjust a flow rate from the nozzle. 24. The method of claim 15 , wherein the second portion of the toolpath comprises sinusoidal geometries, sharp corners and/or sharp 180-degree turns. 25. The method of claim 15 , wherein the coarse gantry moves in a plane. 26. The method of claim 15 , wherein the coarse gantry moves in five axes of motion.