Mixing eductor nozzle and flow control device

What is claimed is: 1. A method, comprising: delivering molten metal through a primary nozzle of a feed tube couplable to a source of the molten metal, the primary nozzle located at a distal end of the feed tube, wherein the primary nozzle is submersible in a molten sump and includes an exit opening through which the molten metal passes; passing the molten metal through a secondary nozzle positioned in alignment with the exit opening of the primary nozzle and submersible within the molten sump, wherein passing the molten metal through the secondary nozzle includes passing the molten metal from the exit opening of the primary nozzle and through a restriction of the secondary nozzle; and inducing supplemental inflow through the secondary nozzle in response to passing the molten metal from the exit opening of the primary nozzle through the secondary nozzle, wherein the supplemental inflow is sourced from the molten sump, and wherein inducing the supplemental inflow comprises generating a low pressure area within the restriction in response to the molten metal from the exit opening of the primary nozzle passing through the restriction of the secondary nozzle. 2. An aluminum product obtained by the method of claim 1 and having a crystalline structure with a maximum standard deviation of grain size at or below 200. 3. The aluminum product of claim 2 , wherein the maximum standard deviation of grain size is at or below 80. 4. The aluminum product of claim 2 , wherein the maximum standard deviation of grain size is at or below 33. 5. The aluminum product of claim 2 , wherein an average grain size is at or below 700 μm. 6. The aluminum product of claim 2 , wherein an average grain size is at or below 400 μm. 7. The aluminum product of claim 2 , wherein delivering molten metal through the primary nozzle includes inducing flow using a flow control device coupled to the feed tube. 8. An apparatus, comprising: a feed tube including a plate nozzle having a first plate and a second plate coupled together in parallel, wherein the feed tube defines a passageway for directing molten metal through the plate nozzle toward at least one exit nozzle; and a secondary nozzle submersible in a molten sump and positionable in alignment with the at least one exit nozzle of the plate nozzle, wherein the secondary nozzle includes a restriction shaped to generate a low pressure area within the restriction to circulate a portion of the molten sump through an entry of the secondary nozzle and through the restriction in response to molten metal from the at least one exit nozzle of plate nozzle passing through the restriction. 9. The apparatus of claim 8 , wherein the at least one exit nozzle includes two exit nozzles for directing the molten metal in non-parallel directions. 10. The apparatus of claim 9 , further comprising an additional secondary nozzle submersible in the molten sump, wherein the additional secondary nozzle is positionable adjacent a second one of the two exit nozzles of the plate nozzle, wherein the additional secondary nozzle includes an additional restriction shaped to generate an additional low pressure area within the additional restriction to circulate an additional portion of the molten sump in response to the molten metal from the second one of the two exit nozzles passing through the additional restriction. 11. The apparatus of claim 8 , further comprising a flow control device coupled to the feed tube for controlling the flow of molten metal through the plate nozzle. 12. The apparatus of claim 8 , wherein the secondary nozzle is removably couplable to the plate nozzle. 13. A system comprising: a feed tube couplable to a source of molten metal; a primary nozzle located at a distal end of the feed tube, wherein the primary nozzle is submersible in a molten sump for delivering the molten metal to the molten sump and wherein the primary nozzle includes an exit opening through which the molten metal passes; and a secondary nozzle submersible in the molten sump and positionable in alignment with the exit opening of the primary nozzle, wherein the secondary nozzle comprises a flow passage that is shaped as a molten flow restriction that generates a low pressure area therein to circulate the molten sump through an entry of the secondary nozzle and through the restriction in response to the molten metal from the exit opening of the primary nozzle passing through the restriction. 14. The system of claim 13 , wherein the molten sump is liquid metal of an ingot being cast. 15. The system of claim 13 , wherein the molten sump is liquid metal within a furnace. 16. The system of claim 13 , wherein the secondary nozzle is coupled to the primary nozzle. 17. The system of claim 13 , additionally comprising a flow control device adjacent the feed tube for controlling flow of the molten metal through the primary nozzle. 18. The system of claim 13 , wherein the primary nozzle is rectangular in shape. 19. The system of claim 13 , wherein the feed tube further includes a second primary nozzle located at the distal end of the feed tube, wherein the second primary nozzle is submersible in the molten sump for delivering the molten metal to the molten sump; and wherein the system further comprises a second secondary nozzle submersible in the molten sump and positionable adjacent the second primary nozzle, wherein the second secondary nozzle includes a second restriction shaped to generate a second low pressure area to circulate the molten sump in response to the molten metal from the source passing through the second restriction. 20. The system of claim 19 , additionally comprising a flow control device adjacent the feed tube for controlling flow of the molten metal through the primary nozzle and the second primary nozzle.