초록 ▼

A casting device includes a covered crucible having a top opening and a bottom orifice, a lid covering the top opening, a stopper rod sealing the bottom orifice, and a reusable mold having at least one chamber, a top end of the chamber being open to and positioned below the bottom orifice and a vacu

A casting device includes a covered crucible having a top opening and a bottom orifice, a lid covering the top opening, a stopper rod sealing the bottom orifice, and a reusable mold having at least one chamber, a top end of the chamber being open to and positioned below the bottom orifice and a vacuum tap into the chamber being below the top end of the chamber. A casting method includes charging a crucible with a solid material and covering the crucible, heating the crucible, melting the material, evacuating a chamber of a mold to less than 1 atm absolute through a vacuum tap into the chamber, draining the melted material into the evacuated chamber, solidifying the material in the chamber, and removing the solidified material from the chamber without damaging the chamber.

대표청구항 ▼

1. A casting method comprising: charging a crucible with a solid material exhibiting a minimum temperature of melting;heating a reusable mold comprising a plurality of mold chambers symmetrically distributed around and angularly offset from a central axis of the reusable mold, and having a first por

1. A casting method comprising: charging a crucible with a solid material exhibiting a minimum temperature of melting;heating a reusable mold comprising a plurality of mold chambers symmetrically distributed around and angularly offset from a central axis of the reusable mold, and having a first portion and defined by an outer wall of an inner member having a cone shape and a remaining portion of the mold chamber being defined by an inner wall of a complementary outer member having a cup shape complementary to the cone shape of the inner member and having the inner member received therein to a temperature greater than 100 ° C. but less than the minimum temperature of melting with an induction heating coil positioned around an outer wall of the complementary outer member and having a conical shape complementary to the outer wall of the complementary outer member;heating the crucible to greater than the minimum temperature of melting and melting the solid material with a second induction heating coil separate from the induction heating coil positioned around the reusable mold;evacuating the plurality of mold chambers to a pressure of less than 1 atm absolute through at least one vacuum tap located below a top end of the plurality of mold chambers positioned below a closed bottom orifice of the crucible;opening the closed bottom orifice of the crucible, draining the melted material through the top end into the evacuated plurality of mold chambers by flowing the melted material over a peak of the cone-shaped inner member and into each mold chamber of the plurality of mold chambers, and solidifying the melted material in the at least one mold chamber; andremoving the solidified material from the plurality of mold chambers by separating the inner member from the complementary outer member of the reusable mold. 2. The method of claim 1, further comprising: covering the crucible before heating the crucible;evacuating the covered crucible to a vacuum less than 1 atm absolute; andpressurizing the evacuated, covered crucible with an inert gas to a pressure greater than the vacuum. 3. The method of claim 2, further comprising employing argon as the inert gas. 4. The method of claim 1, further comprising: evacuating a sealed vessel surrounding the crucible and the mold to a vacuum less than 1 atm absolute; andpressurizing the sealed vessel with an inert gas to a pressure greater than the vacuum within the sealed vessel. 5. The method of claim 4, further comprising locating the sealed vessel in an isolated chamber and performing the method using manipulations remotely controlled from outside the isolated chamber. 6. The method of claim 1, wherein solidifying the melted material comprises solidifying a melted, recycled nuclear fuel alloy. 7. The method of claim 1, further comprising generating electromagnetic stirring forces in melted material in the crucible using the second induction heating coil. 8. The method of claim 1, further comprising initiating a pressure difference of at least 1 atm between the crucible and the plurality of evacuated mold chambers prior to opening the closed bottom orifice. 9. The method of claim 1, wherein draining the melted material comprises draining substantially all of the melted material from the crucible. 10. The method of claim 1, wherein solidifying the melted material comprises draining the melted material into a removable sheath disposed within and extending along at least one mold chamber of the plurality of mold chambers. 11. The method of claim 1, wherein solidifying the melted material comprises forming a cylindrical shape of solidified material that exhibits an aspect ratio of at least about 30. 12. The method of claim 1, further comprising performing the method in the absence of any active cooling. 13. A casting method comprising: charging a crucible with a solid material exhibiting a minimum temperature of melting;evacuating the crucible to a vacuum less than 1 atm absolute;pressurizing the evacuated crucible with an inert gas to a pressure greater than the vacuum;heating a reusable mold comprising a plurality of mold chambers symmetrically distributed around and angularly offset from a central axis of the reusable mold, and having a first portion and defined by an outer wall of an inner member having a cone shape and a remaining portion of the mold chamber being defined by an inner wall of a complementary outer member having a cup shape complementary to the cone shape of the inner member and having the inner member received therein to greater than 100 ° C. but less than the minimum temperature of melting with an induction heating coil positioned around an outer wall of the complementary outer member and having a shape complementary to the outer wall of the complementary outer member;heating the crucible to greater than the minimum temperature and completely melting the material with a second induction heating coil separate from the induction heating coil positioned around the reusable mold;evacuating a plurality of chambers of the mold positioned below a closed bottom orifice of the crucible to a pressure of at least 1 atm less than the pressure of the pressurized crucible through vacuum taps formed in the mold at a base of the plurality of chambers; andopening the bottom orifice of the pressurized crucible, draining substantially all of the melted material from the pressurized crucible, simultaneously distributing the drained melted material among the plurality of evacuated chambers through the top ends thereof into the plurality of evacuated chambers by flowing the melted material over a peak of the cone-shaped inner member and into each mold chamber of the plurality of mold chambers, solidifying the melted material in the plurality of chambers, and removing the solidified material comprising separating the inner member from the complementary outer member. 14. The method of claim 13, further comprising: evacuating a sealed vessel surrounding the crucible and the mold to a vacuum less than 1 atm absolute; andpressurizing the sealed vessel with an inert gas to a pressure greater than the vacuum. 15. The method of claim 14, further comprising locating the sealed vessel in an isolated chamber, performing the method using manipulations remotely controlled from outside the isolated chamber, and wherein solidifying the melted material comprises solidifying a recycled nuclear fuel alloy. 16. The method of claim 13, further comprising generating electromagnetic stirring forces in melted material in the crucible using the second induction heating coil.