Patent Number: 054105773
Section: claims

1. A core-melt source reduction system which is supported within a nuclear reactor containment structure for catching and stopping the progression of a molten core during a core meltdown accident such that the containment structure of the reactor does not deteriorate, the core-melt source reduction system comprising: a plurality of layers of a first material for chemically reacting with the molten core to absorb the molten core, and;  a plurality of layers of lead, one each of said plurality of layers of said lead being disposed between each consecutive pair of said plurality of layers of said first material, each of said plurality of layers of said lead being substantially thinner than each of said plurality of layers of said first material, said plurality of layers of said lead for slowing the progression of the molten core such that the molten core can sufficiently react with said plurality of layers of said first material.  a plurality of layers of a glass material for chemically reacting with the molten core to absorb the molten core, said glass material having a density, said glass material having a softening point lower than 1200.degree. C., said glass material dissolving a portion of the molten core, and;  a plurality of layers of a second material, one each of said plurality of layers of said second material being disposed between each consecutive pair of said plurality of layers of said glass material, each of said plurality of layers of said second material being substantially thinner than each of said plurality of layers of said glass material, said plurality of layers of said second material for slowing the progression of the molten core such that the molten core can sufficiently react with said plurality of layers of said glass material.  a plurality of layers of a glass material for chemically reacting with the molten core to absorb the molten core, said glass material having a density, said glass material having a softening point lower than 1200.degree. C., said glass material dissolving a portion of the molten core, and;  a plurality of layers of lead, one each of said plurality of layers of lead being disposed between each consecutive pair of said plurality of layers of said glass material, each of said plurality of layers of lead being substantially thinner than each of said plurality of layers of said glass material, said lead having a density more than said density of said glass material, said plurality of layers of lead for slowing the progression of the molten core such that the molten core can sufficiently react with said plurality of layers of said glass material.  a plurality of layers of a glass material for chemically reacting with the molten core to absorb the molten core, said glass including lead oxide for chemically reacting with the molten core such that the reaction products are stable in the presence of air and water and;  a plurality of layers of a second material, one each of said plurality of layers of said second material being disposed between each consecutive pair of said plurality of layers of said glass material, each of said plurality of layers of said second material being substantially thinner than each of said plurality of layers of said glass material, said plurality of layers of said second material for slowing the progression of the molten core such that the molten core can sufficiently react with said plurality of layers of said glass material.  a plurality of layers of a glass material for chemically reacting with the molten core to absorb the molten core, said glass material being comprised of 1 to 4 moles of lead oxide and 1 mole of boron oxide, and;  a plurality of layers of a second material, one each of said plurality of layers of said second material being disposed between each consecutive pair of said plurality of layers of said glass material, each of said plurality of layers of said second material being substantially thinner than each of said plurality of layers of said glass material, said plurality of layers of said second material for slowing the progression of the molten core such that the molten core can sufficiently react with said plurality of layers of said glass material. 2. The core-melt source reduction system of claim 1 wherein said first material is glass. 3. The core-melt source reduction system of claim 2 wherein said glass has a softening point lower than 1200.degree. C. said glass having a density less than a density of said second material, said glass being able to dissolve a portion of the molten core. 4. The core-melt source reduction system of claim 2 wherein said glass includes a sacrificial metal oxide for reacting with the molten core such that the reaction products are stable in the presence of air and water. 5. The core-melt source reduction system of claim 4 wherein said sacrificial metal oxide is lead oxide. 6. The core-melt source reduction system of claim 2 wherein said glass is comprised of 1 to 4 moles of lead oxide and 1 mole of boron oxide. 7. The core-melt source reduction system of claim 1 wherein said system includes thermal insulation surrounding said system and resting on the containment structure, said insulation for protecting the containment structure from high temperatures. 8. A core-melt source reduction system which is supported within a nuclear reactor containment structure for catching and stopping the progression of a molten core during a core meltdown accident such that the containment structure of the reactor does not deteriorate, the core-melt source reduction system comprising: 9. The core-melt source reduction system of claim 8 wherein said glass material includes a sacrificial metal oxide for reacting with the molten core such that the reaction products are stable in the presence of air and water. 10. The core-melt source reduction system of claim 9 wherein said sacrificial metal oxide is lead oxide. 11. The core-melt source reduction system of claim 8 wherein said density of said glass material is less than a density of said second material. 12. The core-melt source reduction system of claim 8 wherein said glass material is comprised of 1 to 4 moles of lead oxide and 1 mole of boron oxide. 13. The core-melt source reduction system of claim 8 wherein said second material is lead. 14. The core-melt source reduction system of claim 8 wherein said system includes thermal insulation surrounding said system and resting on the containment structure, said insulation for protecting the containment structure from high temperatures. 15. A core-melt source reduction system which is supported within a nuclear reactor containment structure for catching and stopping the progression of a molten core during a core meltdown accident such that the containment structure of the reactor does not deteriorate, the core-melt source reduction system comprising: 16. The core-melt source reduction system of claim 15 wherein said glass material includes a sacrificial metal oxide for reacting with the molten core such that the reaction products are stable in the presence of air and water. 17. The core-melt source reduction system of claim 16 wherein said sacrificial metal oxide is lead oxide. 18. The core-melt source reduction system of claim 15 wherein said glass material is comprised of 1 to 4 moles of lead oxide and 1 mole of boron oxide. 19. The core-melt source reduction system of claim 15 wherein said system includes thermal insulation surrounding said system and resting on the containment structure, said insulation for protecting the containment structure from high temperatures. 20. A core-melt source reduction system which is supported within a nuclear reactor containment structure for catching and stopping the progression of a molten core during a core meltdown accident such that the containment structure of the reactor does not deteriorate, the core-melt source reduction system comprising: 21. The core-melt source reduction system of claim 20 wherein said glass has a softening point lower than 1200.degree. C., said glass having a density less than a density of said second material, said glass being able to dissolve a portion of the molten core. 22. The core-melt source reduction system of claim 20 wherein said glass is comprised of 1 to 4 moles of lead oxide and 1 mole of boron oxide. 23. The core-melt source reduction system of claim 22 wherein said second material is stainless steel. 24. The core-melt source reduction system of claim 20 wherein said second material is lead. 25. The core-melt source reduction system of claim 20 wherein said system includes thermal insulation surrounding said system and resting on the containment structure, said insulation for protecting the containment structure from high temperatures. 26. A core-melt source reduction system which is supported within a nuclear reactor containment structure for catching and stopping the progression of a molten core during a core meltdown accident such that the containment structure of the reactor does not deteriorate, the core-melt source reduction system comprising: 27. The core-melt source reduction system of claim 26 wherein said glass has a softening point lower than 1200.degree. C., said glass having a density less than a density of said second material, said glass being able to dissolve a portion of the molten core. 28. The core-melt source reduction system of claim 26 wherein said glass includes a sacrificial metal oxide for reacting with the molten core such that the reaction products are stable in the presence of air and water. 29. The core-melt source reduction system of claim 28 wherein said sacrificial metal oxide is lead oxide. 30. The core-melt source reduction system of claim 26 wherein said second material is stainless steel. 31. The core-melt source reduction system of claim 21 wherein said second material is lead. 32. The core-melt source reduction system of claim 26 wherein said system includes thermal insulation surrounding said system and resting on the containment structure, said insulation for protecting the containment structure from high temperatures.