Riserless transfer pump and mixer/pre-melter for molten metal applications

The invention claimed is: 1. A molten metal pump comprising: an elongated body having an internal cavity defined by an inner wall which terminates in a bottom end; and a centrifugal impeller seated in an opening formed in the center of said bottom end, wherein molten metal ejected from the impeller is received by the inner wall adjacent the bottom end; and a helical guidance vane formed by grooves in said inner wall starting proximate to said impeller; whereby rotation of the impeller results in the ejected flow of molten metal to create an axially lifting vortex which climbs the body's inner wall to an outlet opening passing through an upper portion of said body. 2. A pump as defined in claim 1 , wherein said impeller has vertically downward facing liquid inlets. 3. A pump as defined in claim 2 , further comprising a drive shaft extending concentrically down through the tube and attached to a hub formed in a back plate of said impeller. 4. A pump as defined in claim 3 , wherein said impeller includes a plurality of radially extending spaced vanes on an upper surface of said back plate, wherein adjacent vanes define channels each having a channel inlet open to said internal cavity and a channel outlet facing said inner wall. 5. A pump as defined in claim 4 , wherein said impeller has an outer diameter which is approximately one-fourth to one-third of the diameter of said inner wall, said diameter is a function of a particular specific speed of said impeller. 6. A pump as defined in claim 1 , wherein said impeller has an outer diameter which is approximately one-third to one-half of the diameter of said inner wall, said outer diameter is a function of a particular application chosen between a transfer application, a mixing application, and a pre-melting application. 7. A pump which is immersible in a bath of molten metal, comprising: a vertical body having an inner wall which defines an internal cavity and having outlet means formed at an upper end of the body which fluidly connects the internal cavity to transfer means external to said body, said body having a bottom end which depends inwardly from said inner wall; a centrifugal impeller rotatably seated coaxially within an opening formed in the center of said bottom end, wherein molten metal ejected from the impeller is received by said inner wall; whereby rotation of the impeller results in the ejected molten metal to create an axially lifting vortex within said body and along said inner wall, said vortex climbs the inner wall to said outlet means. 8. A pump as defined in claim 7 , wherein said bottom end has a curvature selected from a single point curvature shape and a multiple point curvature shape. 9. A pump as defined in claim 8 , wherein said curvature shape is matched to a particular uplifting axial vortex created by said impeller consisting of a forced vortex, a highly forced vortex, and a super-forced vortex. 10. A pump as defined in claim 8 , wherein said vortex has a substantially uniform thickness along said inner wall and above said bottom end. 11. A pump as defined in claim 8 , further comprising means for mixing solid particulate matter within said vortex, wherein said mixing means is formed within an upper face of said impeller and is effective to redirect said solid particulate matter radially into said uplifting axial vortex. 12. A pump as defined in claim 11 , wherein said impeller has liquid inlet openings in a bottom face, said impeller further comprising a plurality of spaced vane arms extending radially along a top face disposed opposite to the bottom face, wherein said spaced vane arms define a plurality of channels having channel inlets which are open axially to said internal cavity and channel outlets which are open radially to said internal cavity. 13. A pump as defined in claim 11 , wherein the solid particulate matter entering said channel inlets is ejected through said channel outlets and into said uplifting axial vortex such that said ejected solid particulate matter is fully immersed within said vortex. 14. A pump as defined in claim 11 , wherein said impeller has an outer diameter which is approximately one-fourth to one-half of the diameter of said inner wall, said impeller diameter is a function of both a particular specific speed of said impeller and of a particular application chosen between a transfer application, a mixing application, and a pre-melting application. 15. A pump as defined in claim 7 comprising: at least one helical guidance vane climbing inwardly along said inner wall, starting proximate to an outlet opening of said impeller. 16. A method of processing molten metal, comprising the steps of: providing a pump including a vertical tube-like body and a centrifugal impeller rotatably seated coaxially within an opening formed through a bottom end of said body, wherein said impeller has liquid inlets facing downwardly out of said body; immersing said bottom end of said pump within a bath of molten metal; rotating said impeller within said tube-like body to pull molten metal into said liquid inlets and accelerate said molten metal both radially and tangentially within said body such that molten metal ejected from the impeller forms an uplifting axial vortex along an inner wall of said body; and controlling the speed of said impeller to cause said vortex to climb said inner wall up to and out of an outlet formed in an upper end of said body above a metal line of said molten metal bath. 17. A method as defined in claim 16 , wherein said step of providing a pump further comprises the step of forming a radial vane impeller into an upper face of said impeller opposite to said liquid inlets. 18. A method as defined in claim 17 , further comprising the steps of: melting solid metal particles by injecting said solid metal particles into said tube-like body and into inlets in said radial vane impeller, whereby rotation of said impeller accelerates said solid metal particles radially outward to penetrate said vortex created within said body. 19. A method as defined in claim 16 , wherein said vortex has a substantially uniform thickness along said riser tube. 20. A method as defined in claim 16 further comprising the step of: guiding the molten metal ejected from said impeller with at least one helical vane formed within said inner wall.