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A method of forming a gun ammunition projectile 52 including a leading end defined by an ogive 53 including the steps of admixing a quantity of a first powdered metal having a first melting point and a first density, with a quantity of a second powdered metal having a second, and lower, melting poin

A method of forming a gun ammunition projectile 52 including a leading end defined by an ogive 53 including the steps of admixing a quantity of a first powdered metal having a first melting point and a first density, with a quantity of a second powdered metal having a second, and lower, melting point and a second, and lesser, density, pressing a quantity of the admixed metal powders into a self-supporting compact having at least an outboard end disposing the compact in a cup-shaped jacket, heating the compact in the jacket, in a vertical attitude, to a temperature of at least the melting point of the second metal but less than the melting point of the first metal, for a time sufficient to result in a liquefied portion of the second metal migrating to and accumulating at the one outboard end of the compact.

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1. A method of forming a gun ammunition projectile including a leading end defined by an ogive including the steps ofadmixing a quantity of a first powdered metal having a first melting point and a first density with a quantity of a second powdered metal having a second, and lower, melting point and

1. A method of forming a gun ammunition projectile including a leading end defined by an ogive including the steps ofadmixing a quantity of a first powdered metal having a first melting point and a first density with a quantity of a second powdered metal having a second, and lower, melting point and a second, and lesser, density than said first metal, pressing a quantity of said admixed powdered metals into a self-supporting compact having at least an outboard end, introducing said compact into a cup-shaped jacket, having an open end, with said outboard end of said compact disposed internally of and adjacent said open end of said jacket, heating said compact in said jacket to a temperature of at least the melting point of said second metal but less than the melting point of said first metal, for a time sufficient to result in a liquefied portion of said second metal migrating to and accumulating at said one outboard end of said compact, said accumulated second metal being disposed within said jacket. 2. The method of claim 1 and including the step of cooling said heated compact in said jacket to solidify said accumulated portion of said second metal.3. The method of claim 2 and including the step of die-forming said solidified accumulated portion of said second metal within said jacket into a substantially flat disc geometry integral with said at least outboard end of said compact.4. The method of claim 2 and including the step of die-forming said accumulation of said second metal in said jacket, at least a portion of said compact, and the leading end of the said jacket into an ogive geometry.5. The method of claim 4 and including the step of die-pressing said accumulation of said second metal into a substantially flat disc prior to die-forming said ogive.6. The method of claim 1 wherein said first metal is tungsten.7. The method of claim 1 wherein said second metal is tin, lead, iron, aluminum, magnesium, bismuth or mixtures or alloys thereof.8. The method of claim 7 wherein said first and second powdered metals each exhibits an average particle size of about 325 mesh or smaller.9. The method of forming a gun ammunition projectile including a leading end defined by an ogive including the steps ofadmixing a quantity of a first powdered metal having a first melting point and a first density with a quantity of a second powdered metal having a second, and lower, melting point and a second, and lesser, density than said first metal, pressing a quantity of said admixed metal powders into a self-supporting compact of a substantially elongated geometry having a longitudinal centerline and at least an outboard end, introducing said compact into a cup-shaped jacket having an open end, with said outboard end of said compact disposed internally of and adjacent said open end of said jacket, while said compact within said jacket is oriented with said longitudinal centerline of said compact disposed essentially vertical and said outboard end thereof disposed most vertical of the compact, heating said compact in said jacket to a temperature of at least the melting point of said second metal powder but less than the melting point of said first metal powder, for a time sufficient to result in a liquefied portion of said second metal powder migrating to and accumulating at said one outboard end of said compact. 10. A projectile manufactured in accordance with the method of claim 9.11. A round of gun ammunition comprising a projectile produced in accordance with the method of claim 10.12. A method of forming a gun ammunition projectile including a leading end defined by an ogive including the steps ofadmixing a quantity of powdered tungsten with a quantity of either powdered tin, zinc, iron, aluminum, magnesium, bismuth or mixtures or alloys thereof, pressing a quantity of said admixed powdered metals into a self-supporting compact having at least an outboard end, introducing said compact into a cup-shaped metal jacket, having an open end, with said outboard end of said compact disposed internally of and adjacent said open end of said jacket, heating said compact in said jacket to a temperature of at least the melting point of said second metal but less than the melting point of said tungsten, for a time sufficient to result in a liquefied portion of said second metal migrating to and accumulating at said one outboard end of said compact, said accumulated second metal being disposed within said jacket. 13. The method of claim 12 wherein said second metal is tin.14. The method of claim 12 wherein each of said tungsten and second metal powders exhibits a particle size of about 325 mesh.15. The method of claim 12 wherein said tungsten and said second metal are present in the admixture in a ratio of about 60% tungsten, by weight, and about 40%, by weight, of said second metal.16. The method of claim 12 and including the step of, after cooling, die-pressing said cooled compact in said jacket in an axial direction to deform said projection of second metal sufficiently to cause said second metal to define a substantially disc geometry which substantially closes said open end of said jacket.17. The method of claim 16 and including the step of forming an ogive on the open end of said jacket, said ogive including said disc and at least a portion of said outboard end of said compact.18. In a method for the formation of a powder-based projectile for gun ammunition from a cup-shaped metal jacket having an open end and a core having an outboard end and being defined by a self-supporting compact of multiple metal powders, at least one of which is tungsten and at least one of which is a metal having a density and melting points less than the density and melting points of tungsten disposed within the jacket, the improvement comprising heating said jacket/core combination to a temperature of at least the melting point of said metal of lower density and lower melting point whereby said metal of lower density and lower melting point liquefies and at least a portion thereof migrates to and accumulates at the outboard end of said core.19. The improvement of claim 18 wherein said second metal is tin, zinc, iron, copper, aluminum, magnesium, bismuth or mixtures or alloys thereof.20. The improvement of claim 18 wherein each of said tungsten and second metal powders exhibits a particle size of about 325 mesh.21. The improvement of claim 18 wherein said tungsten and said second metal are present in the admixture in a ratio of about 60% tungsten, by weight, and about 40%, by weight, of said second metal.