Patent Number: 051924927
Section: claims

1. The method of reducing exposure of a human within the space between an inner tube co-axial with an outer tube to harmful radiation emitted by a radiation emitting structure within said inner tube, said inner tube having a liquid impenetrable outer surface portion which encircles at least a portion of said radiation emitting structure and said outer tube having a liquid impenetrable inner surface portion facing and coextensive with said outer surface portion and spaced from said outer surface to define said space, said space normally having liquid communication with the interior of said inner tube at one end of said space and said interior of said inner tube containing a liquid which absorbs said radiation and which normally enters into said space, said method comprising: installing a liquid seal at said one end of said space for preventing the flow of said liquid into said space from said interior of said inner tube, the installation of said liquid seal comprising encircling a circumferential portion of said outer surface portion of said inner tube at sad end of said space with a plurality of inflatable tubes disposed end-to-end in liquid sealing relation and inflating said inflatable tubes until said inflatable tubes engage said outer surface portion and said inner surface portion of said outer tube, said inflatable tubes also being deflatable and removable from between said inner tube and said outer tube and performing one of the following two steps:  (a) during the installation of said liquid seal, maintaining said portion of said radiation emitting structure at least substantially covered by said liquid and maintaining said liquid in said space and thereafter, removing at least a portion of said liquid from said space at the side of said liquid seal opposite from said end of said space; and  (b) before the installation of said liquid seal, removing said liquid from said interior of said inner tube until said space is at least partially free of said liquid and thereafter, installing said liquid seal and then adding said liquid to said interior of said inner tube until said radiation emitting structure is at least substantially covered by said liquid.  a seal support ring encircling said outer surface portion at a lower portion thereof, said ring comprising a plurality of arcuate support segments in end-to-end relation and a plurality of such arcuate support segments comprising means engaging said outer surface portion and said inner surface portion;  a plurality of inflatable tube assemblies in end-to-end relation, encircling said outer surface portion and disposed on top of said seal support ring; and  a seal retention ring encircling said outer surface portion and engaging said inflatable tube assemblies at the side thereof opposite from said seal support ring, said seal retention ring comprising a plurality of arcuate retention segments in end-to-end relation and comprising clamping means for clamping the segments to each other in end-to-end relation.  while maintaining said portion of said radiation emitting structure at least substantially covered by said liquid and maintaining said liquid in said space,  installing a removable liquid seal at said one end of said space and in said liquid for preventing the flow of said liquid into said space from said interior of said inner tube after said liquid seal is installed; and  thereafter, removing at least a portion of said liquid from said space at the side of said liquid seal opposite from said end of said space. 2. The method as set forth in claim 1 wherein each said inner tube and said outer tube is a shell of a steam generator and said inner tube and said outer tube are co-axial with a vertical axis, said radiation emitting structure is a plurality of tubes which are supplied with heated fluid containing radioactive particles during operation of the steam generator, said liquid is water and said end of said space is the lower end thereof. 3. The method as set forth in claim 1 further comprising providing an inflatable tube-supporting ring below said inflatable tubes before inflation thereof, said supporting ring comprising a plurality of arcuate ring segments encircling and engaging a circumferential portion of said outer surface portion of said inner tube and engaging said inner surface portion of said outer tube. 4. The method as set forth in claim 3 wherein each of said inflatable tubes comprises an outer inflatable portion and an inner inflatable portion secured together by a membrane and said membrane is placed in engagement with the upper surface of said supporting ring. 5. The method as set forth in claim 4 further comprising providing a seal retention ring intermediate said outer inflatable portion and said inner inflatable portion and on top of said membrane prior to inflating said outer inflatable portion and said inner inflatable portion, said seal retention ring comprising a plurality of arcuate retention segments which are placed successively end-to-end on said membrane and which are clamped together by clamping means, said retention segments having adjustable retention means which is moved into engagement with said outer surface portion of said inner shell. 6. The method as set forth in claim 5 wherein said outer surface portion of said inner tube has the shape of a truncated cone with its smaller diameter below the larger diameter. 7. The method as set forth in claim 5 further comprising superimposing a work platform segment on top of said seal retention ring. 8. The method as set forth in claim 5 further comprising superimposing a work platform ring on said seal retention ring by adding a plurality of arcuate work platform segments on top of said seal retention ring. 9. The method as set forth in claim 8 wherein said plurality of arcuate work platform segments are added after inflating said outer inflatable portion and said inner inflatable portion. 10. Apparatus for sealing the space between an inner tube and an outer tube co-axial with a vertical axis with respect to liquid flow into said space, said space being defined by as liquid impenetrable outer surface portion of said inner tube and a liquid impenetrable inner surface portion of said outer tube facing, coextensive with and spaced from said outer surface of said inner tube, said apparatus comprising: 11. Apparatus as set forth in claim 10 further comprising a work platform ring encircling said outer surface portion and mounted on and supported by said retention segments of said seal retention ring, said work platform ring comprising a plurality of arcuate platform segments in end-to-end relation. 12. Apparatus as set forth in claim 10 wherein said means comprises an adjustable screw for engaging said outer surface portion and preventing said arcuate support segments from moving downward under load. 13. Apparatus as set forth in claim 12 wherein each of said inflatable tube assemblies comprises an inner inflatable portion engageable with said outer surface portion, an outer inflatable portion engageable with said inner surface portion and a membrane interconnecting and secured to said inner inflatable portion and said outer inflatable portion. 14. Apparatus as set forth in claim 13 further comprising resilient filler blocks intermediate and engaging adjacent ends of said inflatable tube assemblies and engaging said outer surface portion and said inner surface portion for providing a liquid seal between said adjacent ends. 15. Apparatus as set forth in claim 13 wherein each of said retention segments is intermediate said outer inflatable portion and said inner inflatable portion of said tube assemblies. 16. Apparatus as set forth in claim 15 wherein each of said arcuate retention segments has at least one adjustable screw means for engaging said outer surface portion and preventing said seal retention ring from moving upwardly when upwardly directed forces are applied thereto. 17. The method of reducing exposure of a human within the space between an inner tube co-axial with an outer tube to harmful radiation emitted by a radiation emitting structure within said inner tube, said inner tube having a liquid impenetrable outer surface portion which encircles at least a portion of said radiation emitting structure and said outer tube having a liquid impenetrable inner surface portion facing and coextensive with said outer surface portion and spaced from said outer surface to define said space, said space normally having liquid communication with the interior of said inner tube at one end of said space and said interior of said inner tube containing a liquid which absorbs said radiation, which covers said portion of radiation emitting structure and which normally enters into said space, said method comprising: 18. The method as set forth in claim 17 wherein each said inner tube and said outer tube is a shell of a steam generator and said inner tube and said outer tube are co-axial with a vertical axis, said radiation emitting structure is a plurality of tubes which are supplied with heated fluid containing radioactive particles during operation of the steam generator, said liquid is water and said end of said space is the lower end thereof. 19. The method as set forth in claim 18 wherein the installation of said liquid seal comprises encircling a circumferential portion of said outer surface portion of said inner tube at said end of said space with a plurality of inflatable tubes disposed end-to-end in liquid sealing relation and inflating said inflatable tues until said inflatable tubes engage said outer surface portion and said inner surface portion of said outer tube, said inflatable tubes also being deflatable and removable from between said inner tube and said outer tube. 20. The method as set forth in claim 19 further comprising providing an inflatable tube-supporting ring below said inflatable tubes before inflation thereof, said supporting ring comprising a plurality of arcuate ring segments encircling and engaging a circumferential portion of said outer surface portion of said inner tube and engaging said inner surface portion of said outer tube. 21. The method as set forth in claim 20 wherein each of said inflatable tubes comprises an outer inflatable portion and an inner inflatable portion secured together by a membrane and said membrane is placed in engagement with the upper surface of said supporting ring. 22. The method as set forth in claim 21 further comprising providing a seal retention ring intermediate said outer inflatable portion and said inner inflatable portion and on top of said membrane prior to inflating said outer inflatable portion and said inner inflatable portion, said seal retention ring comprising a plurality of arcuate retention segments which are placed successively end-to-end on said membrane and which are clamped together by clamping means, said retention segments having adjustable retention means which is movable into engagement with said outer surface portion of said inner shell. 23. The method as set forth in claim 22 wherein said outer surface portion of said inner tube has the shape of a truncated cone with its smaller diameter below the larger diameter. 24. The method as set forth in claim 22 further comprising superimposing a work platform segment on top of said seal retention ring. 25. The method as set forth in claim 22 further comprising superimposing a work platform ring on said seal retention ring by adding a plurality of arcuate work platform segments on top of said seal retention ring. 26. The method as set forth in claim 25 wherein said plurality of arcuate work platform segments are added after inflating said outer inflatable portion and said inner inflatable portion.