Patent Number: 053848136
Section: claims

1. A storage container for storing at least one nuclear fuel assembly comprising: a tubular housing having at least one substantially planar exterior surface;  at least one damping slab, having at least one substantially planar surface and at least one peripheral edge bounding said at least one substantially planar surface, and  retaining means for supporting said damping slab with said substantially planar surface of said damping slab adjacent to said exterior surface of said tubular housing, and for preloading said damping slab against said exterior surface,  said retaining means having at least one fixed portion and at least one free end extending from said fixed portion, said fixed portion being securely least one exterior surface, and said free end overlying said damping slab adjacent said peripheral edge and preloading said damping slab against said exterior surface.  said damping slab includes top and bottom opposing edges and said retaining means are located adjacent said top and bottom opposing edges.  said damping means includes two opposing lateral side edges and said retaining means are located adjacent both of said lateral side edges.  said damping slab includes top and bottom opposing edges and two opposing lateral side edges, and  said retaining means are located adjacent said top and bottom opposing edges and said lateral side edges.  said retaining means include a plurality of elongated clip elements, each elongated clip element having an elongated free end and an elongated fixed portion.  said elongated clip element comprises a polygonal shaped plate having an S-shaped bend forming said free end and said fixed portion,  said fixed portion extending from one side of said S-shaped bend along a first plane, and  said free end extending from an opposite side of said S-shaped bend along a second plane offset from and substantially parallel to said first plane.  said retaining means include a plurality of elongated clip elements, each elongated clip element having an elongated fixed portion, a first elongated free end extending from one side of said elongated fixed portion and a second elongated free end extending from an opposite side of said elongated fixed portion.  said elongated clip element comprises a polygonal shaped plate having two S-shaped bends forming said first elongated free end, said second elongated free end and said fixed portion,  said fixed portion extending from one side of a first S-shaped bend along a first plane to one side of a second S-shaped bend, and  said first elongated free end extending from an opposite side of said first S-shaped bend along a second plane offset from and substantially parallel to said first plane, and  said second elongated free end extending from an opposite side of said second S-shaped bend along said second plane offset from and substantially parallel to said first plane.  said elongated clip element comprises a polygonal shaped plate having two S-shaped bends forming said first elongated free end, said second elongated free end and said fixed portion,  said fixed portion including a substantially right angle bend, said fixed portion extending from one side of a first S-shaped bend along a first plane to said right angle bend along a second plane substantially perpendicular to said first plane and extending to one side of a second S-shaped bend, and  said first elongated free end extending from an opposite side of said first S-shaped bend along a third plane offset from and substantially parallel to said first plane, and  said second elongated free end extending from an opposite side of said second S-shaped bend along a forth plane offset from and substantially parallel to said second plane.  an array of storage compartments,  each of said storage compartments comprising:  a tubular housing having at least one substantially planar exterior surface,  at least one damping slab, having at least one substantially planar surface and at least one peripheral edge bounding said at least one substantially planar surface, and  retaining means for supposing said damping slab with said substantially planar surface of said damping slab adjacent to said exterior surface of said tubular housing, and for preloading said damping slab against said exterior surface,  said retaining means having at least one fixed portion and at least one free end extending from said fixed portion, said fixed portion being securely fastened to said at least one exterior surface, and said free end overlying said damping slab adjacent said peripheral edge and preloading said damping means against said exterior surface.  said retaining means is located at discrete positions along the perimeter of said substantially planar surface.  the storage rack further comprises upper and lower end portions; and  support means for strengthening the upper and lower end portions of the storage rack.  the support means include recess means for positioning the storage compartments in alignment.  each storage compartment housing extends along a central axis; and  said support means position each storage compartment to align the central axis thereof in parallel relation with each adjacent storage compartment.  at least one storage compartment has lateral surfaces defined by exterior surfaces of a plurality of adjacent storage compartments.  at least one storage compartment is defined by three or more adjacent storage compartments.  A. an elongated tubular housing extending along a housing axis and having a polygonal cross-section transverse to said housing axis, said housing having at least three lateral sidewalls, at least one of said sidewalls having a substantially planar exterior surface extending substantially parallel to said housing axis, defining a volume interior to said housing for receiving a nuclear fuel rod,  B. one or more elongated damping elements, each of said damping elements being associated with one of said sidewalls having said substantially planar surface, and each of said damping elements having at least one substantially planar lateral surface extending in the direction of elongation of said damping element, and  C. one or more clamp assemblies including means for biasing each of said damping elements against its associated sidewall with said planar surface of said damping element being adjacent to said planar surface of said sidewall, each said biasing means having at least one fixed portion and at least one free end extending from said fixed portion, said fixed portion being securely fastened to said at least one exterior surface, and said free end overlying said damping slab adjacent said peripheral edge and preloading said damping slab against said exterior surface.  A. a plurality of compartments, each of said compartments including:  B. matrix means for establishing the relative position of said compartments whereby each said housing is fixedly positioned with respect to each other with said housing axes mutually parallel. 2. A storage container according to claim 1 wherein said damping slab comprises a neutron-absorbing material. 3. A storage container according to claim 1 wherein said damping includes means for effecting coulomb damping of vibration in said housing. 4. A storage container according to claim 1 wherein said damping slab further comprises stiffening means for reinforcing said tubular housing, 5. A storage container according to claim 1 wherein said damping slab extends substantially over the entirety said substantially planar surface. 6. A storage container according to claim 1 wherein: 7. A storage container according to claim 1 wherein: 8. A storage container according to claim 1 wherein: 9. A storage container according to claim 1 wherein: 10. A storage container according to claim 9 wherein: 11. A storage container according to claim 1 wherein: 12. A storage container according to claim 11 wherein: 13. A storage container according to claim 11 wherein: 14. A storage rack for storing nuclear fuel assemblies comprising: 15. A storage rack according to claim 10 wherein: 16. A storage rack according to claim 10 wherein: 17. A storage rack according to claim 13 wherein: 18. A storage rack according to claim 13, wherein: 19. A storage rack according to claim 10, wherein: 20. A storage rack according to claim 10, wherein: 21. A compartment for supporting therein an elongated nuclear fuel assembly, comprising: 22. A compartment according to claim 21 wherein said housing has four lateral sidewalls which define said interior volume, said interior volume having a substantially square cross-section transverse to said housing axis. 23. A compartment according to claim 21 wherein said housing has three lateral sidewalls which define said interior volume, said interior volume having a substantially triangular cross-section transverse to said housing axis. 24. A compartment according to claim 21 wherein said housing has six lateral sidewalls which define said interior volume, said interior volume having a substantially hexagonal cross-section transverse to said housing axis. 25. A compartment according to claim 18 wherein said clamp assemblies include a plurality of biasing means affixed to said sidewalls at discrete perimeter locations of said damping elements. 26. A compartment according to claim 21 wherein said damping elements are constructed from a neutron absorbing material. 27. A compartment according to claim 26 wherein said neutron absorbing material is selected from the group consisting of borated stainless steel, boral, and borated aluminium. 28. A rack matrix assembly for supporting therein a plurality of elongated nuclear fuel assemblies: 29. A rack matrix assembly according to claim 26 wherein said matrix means includes means for positioning each said housing in a close-packed array. 30. A rack matrix assembly according to claim 27 wherein said matrix means includes means for positioning each said housing whereby the lateral sidewalls of three or more of said housings define an elongated volume therebetween having substantially the same polygonal cross-section as said polygonal cross-section of said housing, said elongated volume for receiving a nuclear fuel rod. 31. A rack matrix assembly according to claim 33 wherein said housing has four lateral sidewalls which define said interior volume, said interior volume having a substantially square cross-section transverse to said housing axis. 32. A rack matrix according to claim 29 wherein the lateral sidewalls of four of said housings define said elongated volume. 33. A rack matrix assembly according to claim 30 wherein said housing has three lateral sidewalls which define said interior volume, said interior volume having a substantially triangular cross-section transverse to said housing axis. 34. A rack matrix according to claim 33 wherein the lateral surfaces of three of said housings define said elongated volume. 35. A rack matrix assembly according to claim 30 wherein said housing has six lateral sidewalls which define said interior volume, said interior volume having a substantially hexagonal cross-section transverse to said housing axis. 36. A rack matrix according to claim 35 wherein the lateral surfaces of six of said housings define said elongated volume. 37. A rack matrix assembly according to claim 28 wherein said housing has four lateral sidewalls which define said interior volume, said interior volume having a substantially square cross-section transverse to said housing axis. 38. A rack matrix assembly according to claim 28 wherein said housing has three lateral sidewalls which define said interior volume, said interior volume having a substantially triangular cross-section transverse to said housing axis. 39. A rack matrix assembly according to claim 28 wherein said housing has six lateral sidewalls which define said interior volume, said interior volume having a substantially hexagonal cross-section transverse to said housing axis. 40. A rack matrix according to claim 26 wherein said clamp assemblies include a plurality of biasing means affixed to said sidewalls at discrete perimeter locations of said clamping elements. 41. A rack matrix according to claim 28 wherein said damping elements are constructed from a neutron absorbing material. 42. A rack matrix according to claim 41 wherein said neutron absorbing material is selected from the group consisting of borated stainless steel, boral, and borated aluminium.