초록 ▼

A method of forming metal spheres includes ejecting a precisely measured droplet of molten metal from a molten metal mass, buffering the molten metal droplet to reduce the internal kinetic energy of the droplet without solidifying the droplet and cooling the buffered droplet until the droplet solidi

A method of forming metal spheres includes ejecting a precisely measured droplet of molten metal from a molten metal mass, buffering the molten metal droplet to reduce the internal kinetic energy of the droplet without solidifying the droplet and cooling the buffered droplet until the droplet solidifies in the form of a metal sphere. An apparatus for fabricating metal spheres includes a droplet generator that generates a droplet from a molten metal mass, a buffering chamber that receives the droplet from the droplet generator, and diminishes internal kinetic energy of the droplet without solidifying the droplet, and a cooling drum that receives the droplet from the buffering chamber, and cools the droplet to the extent that the droplet solidifies into a metal sphere. The apparatus may further include a collector arrangement that receives the metal spheres from the cooling drum and makes the metal sphere available for collection.

대표청구항 ▼

What is claimed is: 1. A process for fabricating metal spheres, comprising: generating a droplet from a molten metal mass; buffering the droplet by diminishing internal kinetic energy of the droplet without solidifying the droplet; and cooling the buffered droplet to the extent that the droplet sol

What is claimed is: 1. A process for fabricating metal spheres, comprising: generating a droplet from a molten metal mass; buffering the droplet by diminishing internal kinetic energy of the droplet without solidifying the droplet; and cooling the buffered droplet to the extent that the droplet solidifies into a metal sphere, wherein cooling the droplet includes enclosing the droplet in a gaseous medium; and controlling the temperature of the gaseous medium; collecting the metal sphere, wherein collecting the metal sphere includes receiving the metal sphere in a reservoir that holds a liquid; receiving the metal sphere and a volume of the liquid in a pipe; and delivering the metal sphere to a collection basket, wherein delivering the metal sphere to the collection basket includes pumping the metal sphere and the volume of the liquid to a level that is higher than a level of the liquid in the reservoir, and depositing the metal sphere and the volume of the liquid into the collection basket; wherein collecting the metal sphere further includes disposing the collection basket in a holding tank. 2. The process of claim 1, wherein controlling the temperature of the gaseous medium includes providing a first fluid at least partially surrounding the gaseous medium. 3. The process of claim 2, wherein controlling the temperature of the gaseous medium includes dispersing a second fluid within the first fluid. 4. The process of claim 3, wherein dispersing the second fluid within the first fluid includes dispersing the second fluid through a plurality of holes in a dispersal tube. 5. The process of claim 3, wherein the first fluid has a first temperature, and the second fluid has a second temperature. 6. The process of claim 1, wherein receiving the metal sphere and a volume of the liquid in a pipe includes allowing the metal sphere to settle in a bend in the pipe. 7. The process of claim 1, wherein buffering the droplet includes enclosing the droplet in a buffering gaseous medium that is separate from the gaseous medium in which the cooling occurs, and controlling the temperature of the buffering gaseous medium. 8. The process of claim 1, wherein collecting the metal sphere further includes removing the collection basket from the holding tank, and allowing the volume of the liquid to pass through openings in the collection basket that are smaller than the metal sphere. 9. The process of claim 8, wherein collecting the metal sphere further includes returning the liquid passing through the openings in the collection basket to the reservoir. 10. The process of claim 9, wherein returning the liquid to the reservoir includes providing a return channel in fluid communication between the holding tank and the reservoir. 11. A process for fabricating metal spheres, comprising: generating a droplet from a molten metal mass; buffering the droplet by diminishing internal kinetic energy of the droplet without solidifying the droplet, in a first medium at a first temperature; cooling the buffered droplet to the extent that the droplet solidifies into a metal sphere, in a second medium at a second temperature; blowing a fluid in a space between the first medium and the second medium to provide temperature separation between the first medium and the second medium; and collecting the metal sphere, wherein collecting the metal sphere includes receiving the metal sphere in a reservoir that holds a liquid; passing the metal sphere and a volume of the liquid to a pipe; and delivering the metal sphere from the pipe to a collection basket; wherein passing the metal sphere and a volume of the liquid to a pipe includes allowing the metal sphere to slide down lower sides of the reservoir that slope toward an opening in the pipe. 12. The process of claim 11, wherein passing the metal sphere and a volume of the liquid to a pipe includes allowing the metal sphere to settle in a bend in the pipe. 13. The process of claim 11, wherein the first medium is a gaseous medium, and buffering the droplet includes controlling the first temperature. 14. The process of claim 11, wherein delivering the metal sphere from the pipe to a collection basket includes pumping the metal sphere and the volume of the liquid to a level that is higher than a level of the liquid in the reservoir, and depositing the metal sphere and the volume of the liquid into the collection basket. 15. The process of claim 14, wherein collecting the metal sphere further includes disposing the collection basket in a holding tank. 16. The process of claim 15, wherein collecting the metal sphere further includes removing the collection basket from the holding tank, and allowing the volume of the liquid to pass through openings in the collection basket that are smaller than the metal sphere. 17. The process of claim 16, wherein collecting the metal sphere further includes returning the liquid passing through the openings in the collection basket to the reservoir. 18. The process of claim 17, wherein returning the liquid to the reservoir includes providing a return channel in fluid communication between the holding tank and the reservoir. 19. A process for fabricating metal spheres, comprising: generating a droplet from a molten metal mass; buffering the droplet by diminishing internal kinetic energy of the droplet without solidifying the droplet, in a first medium at a first temperature; cooling the buffered droplet to the extent that the droplet solidifies into a metal sphere, in a second medium at a second temperature; blowing a fluid in a space between the first medium and the second medium to provide temperature separation between the first medium and the second medium; and collecting the metal sphere, wherein collecting the metal sphere includes receiving the metal sphere in a reservoir that holds a liquid, passing the metal sphere and a volume of the liquid to a pipe, and delivering the metal sphere from the pipe to a collection basket, wherein delivering the metal sphere from the pipe to a collection basket includes pumping the metal sphere and the volume of the liquid to a level that is higher than a level of the liquid in the reservoir, and depositing the metal sphere and the volume of the liquid into the collection basket, and disposing the collection basket in a holding tank. 20. The process of claim 19, wherein collecting the metal sphere further includes removing the collection basket from the holding tank, and allowing the volume of the liquid to pass through openings in the collection basket that ore smaller than the metal sphere. 21. The process of claim 20, wherein collecting the metal sphere further includes returning the liquid passing through the openings in the collection basket to the reservoir. 22. The process of claim 21, wherein returning the liquid to the reservoir includes providing a return channel in fluid communication between the holding tank and the reservoir. 23. The process of claim 19, wherein passing the metal sphere and a volume of the liquid to a pipe includes allowing the metal sphere to slide down lower sides of the reservoir that slope toward an opening in the pipe. 24. The process of claim 19, wherein passing the metal sphere and a volume of the liquid to a pipe includes allowing the metal sphere to settle in a bend in the pipe. 25. The process of claim 19, wherein the first medium is a gaseous medium, and buffering the droplet includes controlling the first temperature. 26. A process for fabricating metal spheres, comprising: generating a droplet from a molten metal mass; ejecting the droplet at a generally upward angle, such that the droplet follows a trajectory that proceeds upward until the droplet reaches a maximum height before descending; buffering the droplet by providing a generally upward flow of gas that slows a rate of descent of the droplet as the droplet is descending and diminishes internal kinetic energy of the droplet without solidifying the droplet; cooling the buffered droplet to an extent that the droplet solidifies into a metal sphere; and collecting the metal sphere, wherein collecting the metal sphere includes allowing the metal sphere to fall into a reservoir that holds a liquid, receiving the metal sphere and a volume of the liquid from the reservoir in a pipe connected to a bottom end of the reservoir, delivering the metal sphere to a collection basket, wherein delivering the metal sphere to the collection basket includes pumping the metal sphere and the volume of the liquid to a collection level that is higher than a level of the liquid in the reservoir, and depositing the metal sphere and the volume of the liquid into the collection basket, and disposing the collection basket in a holding tank, and allowing the volume of the liquid to pass through openings in the collection basket that are smaller than the metal sphere. 27. The process of claim 26, wherein buffering the droplet includes controlling the temperature of the gas. 28. The process of claim 26, wherein receiving the metal sphere and a volume of the liquid from the reservoir in a pipe includes allowing the metal sphere to slide down lower sides of the reservoir that slope toward an opening in the pipe. 29. The process of claim 26, wherein receiving the metal sphere and a volume of the liquid from the reservoir in a pipe includes allowing the metal sphere to settle in a bend in the pipe. 30. The process of claim 26, wherein collecting the metal sphere further includes returning the liquid passing through the openings in the collection basket to the reservoir. 31. The process of claim 30, wherein collecting the metal sphere further includes providing a return channel in fluid communication between the holding tank and the reservoir. 32. The process of claim 26, wherein collecting the metal sphere further includes removing the collection basket from the holding tank.