Multi-wire feeder method and system for alloy sample formation and additive manufacturing

The invention claimed is: 1. A method for producing multiple alloy samples, comprising: furnishing a directional heat source and an integrated multi-wire feed-head, the integrated multi-wire feed-head having a first wire feed exit, a second wire feed exit, and a heat dispensing exit all disposed on a single downward-facing surface; disposing a work-piece surface a fixed distance from the downward-facing surface of the integrated multi-wire feed-head; wherein the integrated multi-wire feed-head and work-piece are configured to allow the feed-head to deliver, through the heat dispensing exit disposed in the downward-facing surface, heat from the directional heat source into a heat-affected region comprising at least a portion of the work-piece surface, wherein the feed-head is further configured to feed, from one or more of the first wire feed exit and a second wire feed exit, the ends of one or more of a multiplicity of wires having diverse compositions into the heat-affected region; the method further comprising: delivering heat and feeding selected lengths of at least two wires having diverse compositions into the heat-affected region to form, on the portion of the work-piece surface, at least a homogeneous molten alloy portion having a composition defined by the cross sectional areas and relative proportions of the selected lengths of the at least two wires; and cooling the homogeneous molten alloy portion to form a solid alloy portion having the same defined composition as the homogeneous molten alloy portion to form one of the multiple alloy samples. 2. The method of claim 1 , wherein the selected lengths of the at least two wires are fed simultaneously into the heat affected region. 3. The method of claim 2 , further comprising, following the delivering heat into the heat-affected region while feeding and melting selected lengths of the at least two wires: delivering heat and feeding second selected lengths of the at least two wires having diverse compositions into the homogeneous molten alloy portion over a second time interval while maintaining the defined composition of the homogeneous molten alloy portion essentially constant during the second time interval; and maintaining an essentially fixed distance between the feed-head and the molten alloy portion during the second interval by increasing the distance between the feed-head and the original work-piece surface to compensate for formation of a solid alloy portion disposed between the homogeneous molten alloy portion and the original work-piece surface. 4. The method of claim 1 , further comprising the step of regulating the selected lengths by regulating the feed rates of the at least two wires over a time interval. 5. The method of claim 1 , further comprising, immediately preceding the step of delivering heat and feeding selected lengths of the at least two wires: delivering heat and feeding a length of one of the at least two wires into the heat affected region to form a molten nucleus on the portion of the work-piece surface, wherein the length is a negligible fraction of the selected length of that wire. 6. The method of claim 5 , wherein the second selected lengths have the same relative proportions as the selected lengths, the feed rates of the at least two wires are fixed over the second time interval and the relative proportions of the second selected lengths are regulated by regulating the relative proportions of the feed rates of the at least two wires. 7. The method of claim 1 , wherein the directional heat source is a laser, an electron beam or a plasma arc. 8. The method of claim 1 , further comprising: creating a shaped component by applying controlled relative motion between feed-head and work-piece while directing heat and feeding the at least two wires to form successive solid alloy layers on selected regions of the work-piece surface, wherein the selective layers comprise a shaped alloy component having a defined composition. 9. The method of claim 8 , further comprising: changing the defined composition of at least a portion of the successive solid alloy layers, wherein the selected layers comprise a shaped alloy component comprising regions of diverse defined alloy compositions. 10. The method of claim 1 , further comprising: creating a combinatorial alloy sample series or library by applying controlled relative motion between feed-head and work-piece and forming, at different locations on the original work-piece surface, a multiplicity of alloy samples have diverse defined compositions and/or diverse thermal histories.