Systems and methods for manufacturing bulked continuous filament

I claim: 1. An apparatus for at least partially removing impurities from a recycled polymer comprising: a multi-rotating screw (MRS) extruder comprising: an MRS Section comprising: a plurality of satellite screws, each of the plurality of satellite screws being mounted to rotate about its respective central axis; and a satellite screw extruder support system that is adapted to orbitally rotate each of the plurality of satellite screws about a main axis as each of the plurality of satellite screws rotate about its respective central axis, the main axis being substantially parallel to each respective central axis; a first single-screw extruder section comprising a first single extruder screw for feeding the recycled polymer into the MRS section; and a second single-screw extruder section comprising a second single extruder screw for transporting the recycled polymer away from the MRS section; a vacuum pump in communication with the MRS section that is adapted to maintain a pressure within the MRS Section below a pressure of about 5 millibars as the recycled polymer passes through the MRS Section; and a controller that operates the vacuum pump to maintain the pressure within the MRS Section below the pressure of about 5 millibars while the MRS extruder is extruding the recycled polymer, wherein: the apparatus further comprises a viscosity sensor that measures a melt viscosity of the recycled polymer after the recycled polymer has passed through the MRS Section; and the controller further operates in a feedback control loop with the viscosity sensor to operate the vacuum pump to further reduce the pressure within the MRS Section in response to using the viscosity sensor to measure an intrinsic viscosity of the recycled polymer that is below a predetermined level. 2. The apparatus of claim 1 , wherein the plurality of satellite screws comprise at least six satellite screws. 3. The apparatus of claim 2 , wherein: the MRS Section comprises a drum that is adapted to rotate about the main axis; the drum defines a respective screw barrel for each of the plurality of satellite screws, each of the respective screw barrels being substantially parallel to the main axis; and each of the plurality of satellite screws is rotatably mounted within its respective screw barrel. 4. The apparatus of claim 1 , wherein: the MRS Section comprises a vacuum attachment portion defining an opening in a housing of the MRS Section; and the vacuum pump is coupled to the vacuum attachment portion and is in communication with the interior of the MRS section via the opening. 5. The apparatus of claim 1 , further comprising a filtration system that includes at least one filter. 6. The apparatus of claim 5 , wherein the at least one filter comprises at least one filter selected from a group consisting of: i. at least one 40 micron screen filter; and ii. at least one 25 micron screen filter. 7. The apparatus of claim 1 , wherein the vacuum pump comprises at least one jet vacuum pump. 8. The apparatus of claim 1 , wherein the vacuum pump comprises at least one mechanical lobe vacuum pump. 9. The apparatus of claim 1 , wherein the predetermined level is about 0.8 dL/g. 10. A multi-screw extruder for at least partially removing impurities from a polymer melt, wherein the multi-screw extruder comprises: an extruder housing; at least four satellite screw disposed within the extruder housing, wherein each of the at least four satellite screws is mounted to rotate about its respective central axis; a pressure regulation system that is adapted to maintain a pressure within the extruder housing below a pressure of about 5 millibars as the polymer melt passes through the multi-screw extruder; a controller that operates the pressure regulation system to maintain the pressure within the extruder housing below the pressure of about 5 millibars while the multi-screw extruder is extruding the polymer melt; a viscosity sensor that measures a melt viscosity of the polymer melt after the polymer melt has passed through the extruder housing; and the controller further operates in a feedback control loop with the viscosity sensor to operate the pressure regulation system to further reduce the pressure within the extruder housing in response to using the viscosity sensor to measure an intrinsic viscosity of the polymer melt that is below a predetermined level. 11. The multi-screw extruder of claim 10 , wherein: the multi-screw extruder further comprises a satellite screw drum that houses the at least four satellite screws; and the satellite screw drum is adapted to orbitally rotate the at least four satellite screws about a main axis as each of the at least four satellite screws rotate about its respective central axis while the polymer melt passes through the multi-screw extruder; and the main axis is substantially parallel to each respective central axis. 12. The multi-screw extruder of claim 11 , wherein each of the at least four satellite screws is adapted to rotate in a direction that is the same as a direction in which the satellite screw drum is adapted to rotate. 13. The multi-screw extruder of claim 11 , wherein each of the at least four satellite screws is adapted to rotate in a direction that is opposite to a direction in which the satellite screw drum is adapted to rotate. 14. A multi-screw extruder for use in extruding a polymer melt, the extruder comprising: a first satellite screw extruder, the first satellite screw extruder comprising a first satellite screw that is mounted to rotate about a central axis of the first satellite screw; a second satellite screw extruder, the second satellite screw extruder comprising a second satellite screw that is mounted to rotate about a central axis of the second satellite screw; a pressure regulation system that is adapted to maintain a pressure within the first and second satellite screw extruders below a pressure of about 5 millibars as the polymer melt passes through the first and second screw extruders; and a controller that operates the pressure regulation system to maintain the pressure within the first and second satellite screw extruders below the pressure of about 5 millibars while the multi-screw extruder is extruding the polymer melt. 15. The multi-screw extruder of claim 14 , wherein the extruder comprises a satellite screw extruder support system that is adapted to orbitally rotate the first and second satellite screws about a main axis as the polymer melt passes through the first and second screw extruders, the main axis being substantially parallel to both: (1) the central axis of the first satellite screw; and (2) the central axis of the second satellite screw. 16. The multi-screw extruder of claim 15 , wherein: the satellite screw extruder support system comprises a drum that is adapted to rotate about the main axis; the drum defines a first screw barrel having a central axis that is substantially parallel to the main axis; the drum defines a second screw barrel having a central axis that is substantially parallel to the main axis; the first satellite screw is rotatably mounted within the first screw barrel; and the second satellite screw is rotatably mounted within the second screw barrel. 17. The multi-screw extruder of claim 16 , wherein: the extruder comprises a third satellite screw extruder, the third satellite screw extruder comprising a third satellite screw that is mounted to rotate about a central axis of the third satellite screw; the pressure regulation system is adapted to maintain a pressure within the