Patent Number: 052971821
Section: claims

1. A method of decommissioning a nuclear reactor including a vessel defining a chamber and reactor internals positioned within said chamber, said method comprising the steps of: encapsulating the vessel and reactor internals into a solid reactor capsule by forming a matrix within the chamber which integrally attaches to the vessel and integrally embeds the reactor internals to create the solid reactor capsule whereby the capsule will have an outer shell which is formed from the vessel and which substantially encases the matrix and thus the reactor internals;  converting the reactor capsule into a plurality of decommissioned segments by cutting the reactor capsule into segments which each include a portion of the outer shell and a portion of the matrix and the reactor internals embedded therein whereby each of the segments includes a portion of the reactor vessel and pieces of the reactor internals;  providing sheets which are dimensioned to cover the exposed surfaces of the matrix of the segments; and  attaching the sheets to the segment to cover the exposed surfaces.  cutting the reactor capsule into a series of sections; and  subsequently cutting each of these sections into a plurality of segments.  providing a fluidized matrix-creating material which may be predictably solidified and which functions as a radioactive shield in its solid state;  introducing the fluidized matrix-creating material into the reactor chamber; and  solidifying the matrix-creating material in such a manner that it integrally attaches to the vessel and integrally embeds the reactor internals to form the reactor capsule.  providing a diamond matrix wire;  providing a hydraulic drive apparatus having a drive wheel;  routing the diamond wire so that it envelopes a cutting area of the reactor capsule;  guiding the wire back to the drive wheel and coupling it thereto; and  rotating the drive wheel so that the diamond wire is pulled through the cutting area of the reactor capsule.  cutting a first section of the capsule;  transferring the first section to a location away from the direct locality of the remaining portion of the capsule;  thereafter cutting a second section from the remaining portion of the capsule; and  transferring the second section of the capsule to a location away from the direct locality of the now remaining portion of the capsule.  attaching lifting lugs to the section; and  coupling the lifting lugs to a crane.  providing a diamond matrix wire;  providing a hydraulic drive apparatus having a drive wheel;  routing the diamond wire so that it envelopes a cutting area of the reactor capsule section;  guiding the wire back to the drive wheel and coupling it thereto; and  rotating the drive wheel so that the diamond wire is pulled through the cutting area of the reactor capsule section.  isolating the nuclear reactor;  encapsulating the vessel and reactor internals into a solid reactor capsule while it is in the operating location by forming a matrix within the chamber which integrally attaches to the vessel and integrally embeds the reactor internals to create the solid reactor capsule whereby the capsule will have an outer shell which is formed from the vessel and which substantially encases the matrix and thus the reactor internals; and  converting the reactor capsule into a plurality of decommissioned segments by cutting the reactor capsule into segments which each include a portion of the outer shell and a portion of the matrix and the reactor internals embedded therein whereby each of the segments includes a portion of the reactor vessel and pieces of the reactor internals;  providing sheets which are dimensioned to cover the exposed surfaces of the matrix of the segments; and  attaching the sheets to the segment to cover the exposed surfaces.  encapsulating portions of the receptacle and internal components into a solid capsule by forming a matrix within the cavity which integrally attaches to the receptacle and integrally embeds the internal components to create the solid capsule whereby the capsule will have an outer shell which is formed from the receptacle and which substantially encases the matrix and thus the internal components;  converting the capsule into a plurality of segments by cutting the capsule into segments which each include a portion of the outer shell and a portion of the matrix and the internal components embedded therein whereby each of the segments includes a portion of the receptacle and pieces of the internal components;  providing sheets which are dimensioned to cover the exposed surfaces of the matrix of the segments; and  attaching the sheets to the segment to cover the exposed surfaces.  encapsulating portions of the vessel and reactor internals into a solid reactor capsule by forming a matrix within the chamber which integrally attaches to the vessel and integrally embeds the reactor internals to create the solid reactor capsule whereby the capsule will have an outer shell which is formed from the vessel and which substantially encases the matrix and thus the reactor internals; and  converting the reactor capsule into a plurality of decommissioned segments by cutting the capsule into segments which each include a portion of the outer shell and a portion of the matrix and the internal components embedded therein whereby each of the segments includes a portion of the receptacle and pieces of the internal components;  providing sheets which are dimensioned to cover the exposed surfaces of the matrix of the segments; and  attaching the sheets to the segment to cover the exposed surfaces.  cutting the reactor capsule into a series of sections; and  subsequently cutting each of these sections into a plurality of segments.  providing a fluidized matrix-creating material which may be predictably solidified and which functions as a radioactive shield in its solid state;  introducing the fluidized matrix-creating material into the reactor chamber; and  solidifying the matrix-creating material in such a manner that it integrally attaches to the vessel and integrally embeds the reactor internals to form the reactor capsule. 2. A method as set forth in claim 1 wherein said cutting step includes the steps of: 3. A method as set forth in claim 1 wherein said encapsulating step includes the step of encapsulating all of the reactor internals into the solid reactor capsule. 4. A method as set forth in claim 1 wherein said matrix-forming step comprises the steps of: 5. A method as set forth in claim 4 wherein said step of providing a fluidized matrix-creating material comprises the step of providing concrete in a fluid form. 6. A method as set forth in claim 1 wherein said step of cutting the reactor capsule includes the step of cutting the reactor capsule into a series of sections which each weigh less than 400 tons. 7. A method as set forth in claim 1 wherein said step of cutting the reactor capsule includes the step of cutting the reactor along horizontal cutting lines each of which creates a section. 8. A method as set forth in claim 7 wherein said step of cutting the reactor capsule includes the step of cutting the reactor along horizontal cutting lines each of which creates a section and each of which passes through both the capsule shell and the capsule center whereby the cutting of the vessel and the reactor internals occurs substantially simultaneously. 9. A method as set forth in claim 1 wherein said step of cutting the reactor capsule includes the step of cutting the reactor along cutting lines each of which creates a section and each of which passes through both the capsule shell and the capsule center whereby the cutting of the vessel and the reactor internals occurs substantially simultaneously. 10. A method as set forth in claim 9 wherein said step of cutting the reactor capsule includes the step of cutting at least some of the sections into semi-sections. 11. A method as set forth in claim 2 wherein said step of cutting the reactor capsule includes the steps of: 12. A method as set forth in claim 1 wherein said step of cutting the reactor capsule includes the steps of: 13. A method as set forth in claim 2 further comprising the step of transferring the series of sections to an appropriate secondary cutting station within a reactor building surrounding the nuclear reactor prior to said subsequent cutting step. 14. A method as set forth in claim 13 wherein said transferring steps include the steps of: 15. A method as set forth in claim 14 wherein said step of attaching lifting lugs includes the step of attaching the lifting lugs to the vessel prior to said encapsulating step. 16. A method as set forth in claim 14 wherein said step of attaching lifting lugs includes the step of attaching the lifting lugs to the shell prior to said cutting step. 17. A method as set forth in claim 13 wherein said transferring step includes the step of transferring at least some of the sections to a dry cutting station. 18. A method as set forth in claim 13 wherein said transferring step includes the step of transferring at least some sections to a wet cutting station. 19. A method as set forth in either of claims 17 or 18 wherein said subsequent cutting step includes the steps of: 20. A method as set forth in claim 1 wherein said step of providing sheets includes the step of providing steel sheets and wherein said step of attaching the sheets to the segments includes the step of welding the sheets to the portion of the outer shell. 21. A method as set forth in claim 20 wherein the vessel is cylindrical whereby said segment includes a wall formed from a portion of the vessel which is curved and wherein said sheets are flat. 22. A method as set forth in claim 21 wherein said step of attaching the sheets to the segments includes the step of securing said sheets to each other. 23. A method of decommissioning an nuclear reactor which is situated in a certain operating location and which includes a vessel defining a chamber and reactor internals positioned within said chamber, said method comprising the steps of: 24. A method of decommissioning a nuclear device including a receptacle defining a cavity and radiation-exposed internal components positioned within the cavity, said method comprising the steps of: 25. A product formed from a decommissioned nuclear reactor which had a vessel defining a chamber and reactor internals situated in the chamber, said product produced by a process which comprises the steps of: 26. A product as set forth in claim 25 wherein said cutting step includes the steps of: 27. A product as set forth in claim 26 wherein said encapsulating step includes the step of encapsulating all of the reactor internals into the solid reactor capsule. 28. A product as set forth in claim 25 wherein said matrix-forming step comprises the steps of: 29. A product as set forth in claim 28 wherein said step of providing a fluidized matrix-creating material comprises the step of providing concrete in a fluid form. 30. A product as set forth in claim 29 wherein said step of cutting the reactor capsule includes the step of cutting the reactor capsule into a series of sections which each weigh less than 400 tons.