Feedblock for manufacturing multilayer polymeric films

The invention claimed is: 1. A feedblock comprising: a first packet creator that forms a first packet including a first plurality of polymeric layers, the first plurality of layers including at least four first individual polymeric layers; a second packet creator that forms a second packet including a second plurality of polymeric layers, the second packet creator separate and distinct from the first packet creator, the second plurality of layers including at least four second individual polymeric layers, wherein the first packet creator is configured such that the first individual polymeric layers are formed at approximately the same time as one another, and the second packet creator is configured such that the second individual polymeric layers are formed at approximately the same time as one another; and a packet combiner configured to combine the first and second packets, the packet combiner comprising: a first channel that receives the first packet from the first packet creator; and a second channel that receives the second packet from the second packet creator, wherein the first channel and the second channel are configured to combine the first and second packets to form a multilayer flow stream including the first plurality of polymeric layers and second plurality of polymeric layers, wherein the first packet creator includes a first plurality of flow channels, a first plurality of conduits, a first plurality of slots, and a first compression section all in fluid communication with each other and configured to generate the first packet having the first plurality of polymeric layers, and wherein the second packet creator includes a second plurality of flow channels, a second plurality of conduits, a second plurality of slots, and a second compression section all in fluid communication with each other and configured to generate the second packet having the second plurality of polymeric layers, wherein the feedblock is configured such that for each primary packet generated in the feedblock, the feedblock includes a separate and distinct packet creator having a separate and distinct plurality of flow channels and a separate and distinct plurality of conduits, wherein the first packet is substantially formed in a first flow direction, the second packet is substantially formed in a second flow direction, and the packet combiner combines the first and second packets in along a longitudinal axis, wherein the first flow direction defines a first angle with the longitudinal axis and the second flow direction defines a second angle with the longitudinal axis, wherein the first and second angles range from approximately 5 degrees to approximately 60 degrees. 2. The feedblock of claim 1 , wherein the feedblock is configured such that the first packet creator is substantially thermally isolated from the second packet creator. 3. The feedblock of claim 1 , wherein the feedblock further comprises a third packet creator that forms a third packet including a third plurality of polymeric layers, wherein the packet combiner further comprises a third channel that receives the third packet from the third packet creator, wherein the first, second and third channels are configured to combine the first, second, and third packets to form the multilayer flow stream, the multilayer flow stream including the first, second, and third plurality of polymeric layers. 4. The feedblock of claim 1 , wherein the first channel and second channels are configured such that the first and second packets are substantially fully stacked when combined with one another. 5. The feedblock of claim 1 , wherein the feedblock further comprises at least one first thermal tuning mechanism proximate to the first packet creator and at least one second thermal tuning mechanism proximate to the second packet creator, wherein the at least one first thermal tuning mechanism is configured to selectively provide heat to a first portion of the first packet creator and the at least one second thermal tuning mechanism is configured to selectively provide heat to a second portion of the second packet creator. 6. The feedblock of claim 1 , wherein the first packet creator is configured to accept a first material and a second material that substantially make up the first plurality of polymeric layers, and the second packet creator is configured to accept a third material and a fourth material that substantially make up the second plurality of polymeric layers. 7. The feedblock of claim 6 , wherein the first material is substantially the same as the third material and the second material is substantially the same as the fourth material. 8. The feedblock of claim 1 , wherein a number of layers in the first plurality of polymeric layers is approximately equal to the second plurality of polymeric layers. 9. The feedblock of claim 1 , further comprising a thermal isolation section that separates at least a portion of the first packet creator from the second packet creator, the thermal isolation section configured to substantially thermally isolate the first and second packet creators from one another. 10. The feedblock of claim 1 , wherein the first and second packet creators comprise one or more inserts, the one or more inserts defining the first plurality of conduits and first plurality of slots of the first packet creator and the second plurality of conduits and second plurality of slots of the second packet creator. 11. The feedblock of claim 10 , wherein the one or more inserts comprise a first insert and a second insert separate from the first insert, the first insert defining the first plurality of conduits and first plurality of slots, and the second insert defining the second plurality of conduits and second plurality of slots. 12. The feedblock of claim 1 , wherein the first and second packet creators comprise a gradient plate manifold, the gradient plate manifold defining the first plurality of flow channels and the second plurality of flow channels. 13. The feedblock of claim 12 , wherein the gradient plate manifold comprises a first gradient plate manifold and a second gradient plate manifold separate from the first gradient plate manifold, the first gradient plate manifold defining the first plurality of flow channels, and the second gradient plate manifold defining the second plurality of flow channels. 14. The feedblock of claim 1 , wherein the first packet flows in the first flow direction within the first compression section, the first plurality of conduits define a third flow direction, and wherein the first flow direction is different from the third flow direction. 15. The feedblock of claim 1 , wherein the first plurality of flow channels is below the first plurality of conduits with regard to the first flow direction. 16. The feedblock of claim 1 , wherein the first and second packet creators form the first and second packets at positions that are staggered relative to the longitudinal axis. 17. The feedblock of claim 1 , wherein the packet combiner comprises a first spreading manifold, the first spreading manifold configured to spread the first plurality of polymeric layers of the first packet in a cross-web direction prior to the first packet being combined with the second packet. 18. The feedblock of claim 17 , wherein the packet combiner includes an extrusion die, the extrusion die including the first spreading manifold. 19. The feedblock of claim 1 , wherein the first plurality of polymeric layers and second plurality of polymeric layers each include at least 20 individual p