Liquefier assembly for use in extrusion-based additive manufacturing systems

The invention claimed is: 1. A liquefier for use in an extrusion-based additive manufacturing system, the liquefier comprising: an upstream portion configured to receive a supply of consumable filament wherein the upstream portion has a substantially smooth upstream inner surface having an upstream inner cross-sectional area; a downstream portion configured to receive the consumable filament from the upstream portion wherein the downstream portion has a substantially smooth downstream inner surface having a downstream inner cross-sectional area wherein the downstream inner cross-sectional areas is greater than the upstream inner cross-sectional area; a shoulder located at an intersection of the upstream portion and the downstream portion wherein the shoulder of the liquefier is configured to restrict upward and downward movements of a melt meniscus of the filament; and a nozzle attached to the downstream portion proximate a distal end wherein the nozzle comprises a substantially smooth tapered surface that transitions the substantially smooth downstream inner surface proximate the distal end of the downstream portion to an extrusion port configured to extrude molten consumable material, wherein the extrusion port has a cross-sectional area that is less than the upstream inner cross-sectional area; and a heater configured to conduct heat to the received filament in the downstream portion to produce a molten material having a meniscus; and a drive mechanism configured to feed the supply of consumable filament to the upstream portion of the liquefier. 2. The liquefier of claim 1 , wherein the inner surface of the upstream portion comprises a material providing the inner surface with a lower coefficient of friction than the substantially smooth downstream inner surface of the downstream portion. 3. The liquefier of claim 2 , wherein the inner surface of the upstream portion comprises a fluorinated polymer. 4. The liquefier of claim 1 , wherein the upstream portion comprises a plurality of apertures each configured to receive a consumable material and wherein the plurality of apertures each has an upstream inner surface with an upstream average inner cross-sectional area. 5. The liquefier of claim 4 , wherein the downstream portion comprises a downstream inner surface having a downstream average inner cross-sectional area that is greater than a sum of the upstream average inner cross-sectional areas of the plurality of apertures. 6. The liquefier of claim 1 , wherein the upstream portion and the downstream portion both have a non-cylindrical geometry. 7. The liquefier of claim 1 , wherein the liquefier further comprises a hollow tube that provide an inner surface in the upstream portion having a low coefficient of friction with respect to the received filament. 8. A liquefier assembly for use in an extrusion-based additive manufacturing system, the liquefier assembly comprising: a liquefier comprising: a main body having a first end and a second end; a flow channel extending from the first end to the second end and having a shoulder positioned between the first end and the second end, the shoulder defining an upstream portion having a substantially smooth inner upstream surface and a downstream portion having a substantially smooth inner downstream surface wherein upstream portion has an upstream inner cross-sectional area and wherein the downstream portion has a downstream inner cross-sectional area and wherein the downstream inner cross-sectional areas is greater than the upstream inner cross-sectional area wherein the shoulder of the liquefier is configured to restrict upward and downward movement of the meniscus while the drive mechanism feeds the filament; and a heater configured to conduct heat to the received filament in the downstream portion to produce a molten material having a meniscus; and a nozzle attached to the main body proximate a second end wherein the nozzle comprises a substantially smooth tapered surface that transitions the substantially smooth downstream inner surface proximate the second end to an extrusion port in communication with the flow channel, the extrusion port having a cross-sectional area that is less than the upstream inner cross-sectional area; and a drive mechanism configured to feed the supply of consumable filament to the upstream portion of the liquefier. 9. The liquefier assembly of claim 8 , wherein the substantially smooth inner surface of the upstream portion has a lower coefficient of friction than the substantially smooth inner downstream surface of the downstream portion. 10. A liquefier for use in an extrusion-based additive manufacturing system, the liquefier comprising: a liquefier tube configured to receive a supply of a consumable filament and having an upstream portion and a downstream portion wherein the downstream portion comprises a substantially smooth inner downstream surface; a shoulder located between the upstream portion and the downstream portion of the liquefier tube; a hollow liner disposed at least partially within the liquefier tube and wherein the hollow liner has a substantially smooth inner liner surface and a distal end that defines the shoulder and wherein the hollow liner provides the liquefier with an upstream cross-sectional area less than the cross-sectional area of the downstream portion of the liquefier; and a nozzle attached to the downstream portion proximate a distal end wherein the nozzle comprises a substantially smooth tapered surface that transitions the substantially smooth downstream inner surface proximate the distal end of the downstream portion to an extrusion port, the extrusion port having a cross-sectional area that is less than the upstream cross-sectional area. 11. The liquefier of claim 10 , wherein the shoulder of the liquefier is configured to restrict upward and downward movements of a melt meniscus of the filament. 12. The liquefier of claim 10 , wherein the inner surface of the hollow liner has a surface having a lower coefficient of friction than the substantially smooth downstream surface of the liquefier tube. 13. The liquefier of claim 10 , wherein the shoulder is positioned at the distal end of the hollow liner, the shoulder having a sloped profile relative to a cross-section of the liquefier assembly, when the cross-section is taken perpendicular to a longitudinal axis of the liquefier assembly. 14. The liquefier of claim 10 , wherein the hollow liner comprises a fluorinated polymer. 15. The liquefier of claim 10 , wherein the upstream portion comprises a plurality of apertures each configured to receive a consumable material and wherein the plurality of apertures each has an upstream inner surface with an upstream average inner cross-sectional area. 16. The liquefier of claim 15 , wherein the downstream portion comprises a downstream inner surface having a downstream average inner cross-sectional area that is greater than a sum of the upstream average inner cross-sectional areas of the plurality of apertures. 17. The liquefier of claim 10 , wherein the upstream portion and the downstream portion both have a non-cylindrical geometry. 18. The liquefier of claim 8 , wherein the substantially smooth inner upstream surface of the upstream portion comprises a fluorinated polymer. 19. The liquefier of claim 8 , wherein the upstream portion and the downstream portion both have a non-cylindrical geometry.