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US3113215A - Cask construction for radioactive material - Google Patents

Cask construction for radioactive material Download PDF

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Publication number
US3113215A
US3113215A US92038A US9203861A US3113215A US 3113215 A US3113215 A US 3113215A US 92038 A US92038 A US 92038A US 9203861 A US9203861 A US 9203861A US 3113215 A US3113215 A US 3113215A
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Prior art keywords
cask
outer shell
construction
fins
heat
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US92038A
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John W Allen
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Stanray Corp
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Stanray Corp
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    • GPHYSICS
    • G21NUCLEAR PHYSICS; NUCLEAR ENGINEERING
    • G21FPROTECTION AGAINST X-RADIATION, GAMMA RADIATION, CORPUSCULAR RADIATION OR PARTICLE BOMBARDMENT; TREATING RADIOACTIVELY CONTAMINATED MATERIAL; DECONTAMINATION ARRANGEMENTS THEREFOR
    • G21F5/00Transportable or portable shielded containers
    • G21F5/06Details of, or accessories to, the containers
    • G21F5/10Heat-removal systems, e.g. using circulating fluid or cooling fins

Definitions

  • This invention relates to casks for transporting radioactive materials; more particularly it relates to casks or containers of minimal dimensions and weight, yet having high strength for transporting intensely radioactive matreials which are exothermic and which may encounter temperatures from heat generated internally of several hundred degrees Fahrenheit during transport. More specifically the invention relates to a cask, suitable for the shipment of intensely radioactive materials which may be exothermic, constructed so as to have very high thermal conductivity to condut the heat from said casks to the ambient air as rapidly as possible.
  • casks may be carried in a truck or on a fiat car and transported to its destination through populated areas and it is necessary that the cask provide ample shielding to prevent exposure to the general public of radiation and heat burns, and yet provide rapid thermal conductivity to release the heat generated within the container.
  • a cask comprising a composite structure incorporating the best features of various materials for the construction of a suitable radiation shielding container, of minimal weight and high thermal conductivity and suitable for transporting intensely radioactive materials safely.
  • the invention comprises briefly a minimum dimension container adapted for transporting intensely radioactive materials, having inner and outer shells in spaced relation, high radiation-shielding material between the shells, the shells being constructed of finned sections to provide high thermal conductivity, the outer shell having attached banks of fins to provide additional thermal conductivity, and the radiation being attenuated by passing transversely through the high density shielding material members or the finned sections.
  • the outer liner consists of bent plates welded together to give a fin surface for heat dissipation to the surrounding air.
  • the space between the outstanding lianges is filled with high heat-conductive material to improve the eiciency of the tins.
  • the space is lled with lead, as the main portion of the lead inside the liner is poured.
  • a strip of aluminum or copper, brazed to the liner material, or held in place by the lead, is used to improve the heat conduction.
  • the liner is constructed of stainless steel to provide a non-corrosive surface which is
  • FIGURE l is a central longitudinal cross sectional view of the preferred form of Cask.
  • FIGURE 2 is a transverse sectional view through a portion of the cask of FIGURE l, showing a high conductive strip brazed to the fin material.
  • FIGURE 3 is a fragmental view, similar to FEGURE 2, showing the conductive strip lead-bonded to the fins.
  • FIGURE 4 is a side elevational view of a portion of a Cask showing a modified auxiliary iin arrangement.
  • FIGURE 5 is a horizontal sectional view through the Cask of FIGURE 4.
  • FIGURE 6 is a partial cross section through a cask having auxiliary cooling fins of slightly different arrangement.
  • FIG- URES l and 2 illustrate a preferred construction of a cask indicated generally by the reference 10.
  • the cask ICC or container llt comprises an outer shell 12 and an inner shell 14 in spaced relation from said outer shell.
  • the cask may be of any suitable configuration although a cylindrical configuration is illustrated in this embodiment.
  • the outer shell i2 is constructed of a plurality of ns i6 each extending from the upper end 18 of the cask to the bottom end 20 and being of a U-shaped construction with legs 22 extending radially with relation to the center line 212- of the cask 10.
  • the fins 16 are spaced apart from each other by means of conducting strips 26.
  • the outer extremities 28, both of the fin legs 22 and of the strips 26, are joined together in any suitable manner such as by the welds 30 so as to present a corrugated or fin surface construction to the outer shell 12.
  • the inner shell 14 is constructed of a liner 32 to which are attached a plurality of longitudinally-extending fluid conducting pipes 34 mounted radially around the liner and in spaced relation to each other.
  • the pipes 34 are interconnected at their upper and lower extremities 36, 3S and extend from upper and lower annular pipes 46, 42.
  • the outer and inner shells 12, 14 are spaced apart by means of structural braces 44 and a suitable filler i6 which may be poured into the space 43 formed between the shells.
  • the braces 44 are spaced from the internal liner 32 by means of suitable supporting structure 56 and are connected to the outer shell l2 by suitable welding 52 to the distorted ns 54.
  • Secondary fins S6, 58 may be mounted on the braces 44 to aid in longitudinal heat conduction.
  • a removable lid et is provided at the top of the cask 10, which is always carried in a vertical position, as shown in FIGURE l.
  • the lid 69 is constructed of an outer head 62 and an inner head 64, the fatter being of a hollow construction and .filled with a suitable filler 66 similar to the filler 46 between the outer and inner shells l2, 14 of the cask it).
  • the outer head 62 and the inner head 64 of the lid 6) are secured together by means of suitable bolts 63.
  • the lid 69 may be removably fastened to the top of the cask l0 by means of bolts 70 and seats on a recessed contour which provides a pressure seal between the cask walls and the lid 60.
  • the outer head 6E seats on a flange '72 and the inner head 64 seats on a step flange 74.
  • Suitable gaskets '76 constructed of resilient material, are provided in recesses 78 in the outer head 62, which gaskets 7d engage the flange 72.
  • the lid 6i) may be provided with a conventional pressure release check valve (not shown), if so desired, having an adjustable pressure release mechanism connecting the interior of the cask with the ambient atmosphere, through an indirect channel to prevent t e escape of nnattenuated radiation, when the pressure within the Cask exceeds the preset release valve.
  • a natural convection liquid circulating system comprises a plurality of pipes 3d positioned within the wall of the cask 1G and next to thc internal liner 32.
  • the pipes 34 are interconnected by means of annular pipes dii, 42 and communicate by way of conduits 80, 82 to an external series of pipes (not shown) for dissipating the heat to the ambient atmosphere.
  • This circulating system may be regulated by means of valves 84, 86 located externally of the outer shell 12 on the conduits Si), $2.
  • the pipes 34 act as internal fins for transferring heat from the internal liner 32 to the filler i6 and thence to the intermediate fins I6 of the outer shell i2 and to the ambient atmosphere.
  • Structural supports for the cask are supplied by external annular ring construction 88 which comprises a plurality of annular members 90, each having an internal wall 92, and an external wall 94, spaced from the internal wall 92 by means of ribs 95. Supported trunnions 93 for carry- 3 ing the cask extend through the external ring construction 88.
  • Conduits 80, 82 and their valves 84, 86 are located within the structure of the external ring construction 88 for protection from possible damaging Contact during transportation of the Cask 18, as shown in FIG- URE 1.
  • the outer shell 12 is preferably made of a strong structural material to impart strength to the casl; 10.
  • the fins 16 are made of a low conductive material, such as stainless steel, while the conductnig strips 26 are made of a high-conductive material, such as copper or aluminum.
  • the conductivity of stainless steel is only about nine B.t.u. per hour per degree Fahrenheit per foot, while the conductivity of aluminum is one hundred twenty, and copper is two hundred twenty.
  • the internal liner 32 is composed of stainless steel; and the pipes 34, the annular tubes 48, 42 and the conduits 80, 82 are made of highconduetive material such as copper.
  • the fillers 46, 66 are composed of high radiation-shielding material, such as lead, which may be poured between the outer and inner shells 12, 14 and into the hollow inner head 64 of the lid 68.
  • the pipes 34 are brazed to the liner 32, as are the conducting strips 26 to the iins 16.
  • the fin construction 16 of the outer shell 12 presents a large corrugated surface to the lead iiller 46. This is necessary since it is impractical to obtain a 100% true metallic bond between the lead filler 46 and the stainless steel fins 16.
  • the resulting air gap between the lead and the steel presents a heat barrier which is reduced in proportion to the arca of this gap.
  • the iin construction 16, illustrated in FGURES l and 2 provides a large area both to the air gap between the lead and the steel and also to the ambient atmosphere.
  • the ns 16 have a rounded configuration which is smooth and devoid of rough welds and, therefore, facilitates cleaning during decontamination.
  • the welds 38, at the outer extremities 28 of the fins 16 and conducting strips 26, do not transfer heat, so do not require full fusion welding. These wclds are also much more accessible during fabrication of the Cask for the Welding operation and are ground smooth to present an easy surface to clean.
  • the corrugated 1in construction 16 also provides expansion capabilities to provide for expansion of the lead filler 46 due to its increased temperature and high coecient of expansion.
  • FIG. 3 A modification of my invention for Cask construction for transporting thermally hot intensely radioactive material is illustrated in FGURE 3 in which the caslr is shown generally by the reference 188 and is comprised of an internal shell (not shown), similar to that illustrated in FIGURES 1 and 2, and an external shell 102 having a plurality of radially aligned V-shaped fins 1114 spaced apart by means of conducting strips 106.
  • the fins 104 and conducting strips 166 are outwardly joined together by means of suitable Welds 108.
  • FIGURES 4 and 5 A third embodiment of my invention is illustrated in FIGURES 4 and 5, in which the caslt is shown generally by the reference 110 and is comprised of outer and inner shells 112, 114 in spaced relation from each other.
  • the outer shell 112 is constructed of a plurality of radially aligned U-shaped fins 116 spaced apart by means of conducting strips 118, said tins 116 and conducting strips 118 being outwardly joined together by means of suitable welds 128.
  • Intersticed between groups of the fins 116 and conducting strips 118 are a plurality of H-shaped wedge-receiving tins 122 having a radially outwardlyfacing recess 124, formed between the radially outwardlyextending legs 126, 128, and an inwardly-oriented recess 130, formed between the inwardly-extending askew legs 132, 134.
  • the legs 126, 132 and 128, 134 of the hns 122 are spaced apart by means of post 136.
  • These conducting ns 122 are internally seated within and brazed to a liner 138 which forms an RVi-shaped extension of the fins 116.
  • the inner shell 114 is constructed of a liner 148 t0 which are brazed a plurality of radially-aligned internal fins 142, which have legs 144 directed to dissipate heat toward the recess of the conducting fins 122 of the outer shell 112.
  • Adapted to seat within the recesses 124 of the wedge-receiving tins 122 are a series of external fins 146 each constructed of a supporting wedge member 148 from which extend a plurality of closely-spaced fin blades 15).
  • the auxiliary iins 146 may be removably mounted to the cask 11G by means of suitable bolts 152.
  • Between the outer and inner shells 112, 114 is poured a suitable radiation-shielding iiller 154.
  • a removable lid 156 is mounted on the top of the cask 110 by means of suitable bolts 158.
  • the internal liner and outer shell fins 116 are constructed of stainless steel, the internal fins 142, conducting strips 118 and conducting ns 122 are made of copper, and the auxiliary tins 146 are made of aluminum, While the filler 154 is lead.
  • FIGURE 6 A fourth embodiment of my invention is illustrated in FIGURE 6, in which the cask is shown generally by the reference 168.
  • the cask 1611 is hexagonal in configuration and is comprised of an outer shell 162 spaced apart from an inner shell 164.
  • the outer shell 162 is constructed of a plurality of U-shaped fins 166, made of a low-conductive material, such as stainless steel, said ns 166 being spaced apart by means of structural blocks 168, also made of stainless steel.
  • Imbedded in the structural blocks 168 are inwardly-extending conducting strips 170, made of a high-conductive material, such as copper.
  • the innermost extremities 172 of the conducting strips 170 are structurally supported and brazed to braces 174, also made of a high heat-conductive material, such as copper.
  • the inner shell 164 is constructed of an internal liner 176, made of a low-conductive material such as stainless steel, to which is attached a plurality of internal tins 178 of high heat-conductive material, such as copper.
  • the outer extremities 186 of the internal ins 178 are structurally supported by and brazed to the braces 1'74.
  • a suitable high radiation-shielding material, such as lead, is poured into the space between the outer and inner shells 162, 164 to form a filler 182.
  • Auxiliary removable fins 184 are mounted externally on the Cask 160, and each comprises a supporting member 186 from which extends a plurality of closely-spaced iin blades 188.
  • the inner end 190 of the supporting members 186 is mounted in a flat surface contact 192, made of a soft material, such as soft copper, for intimate contact with the structural blocks 168 0f the outer Shell 162.
  • the outer end 194 of the supporting members 186 is mounted in a frame 196 which is bolted by means of suitable bolts 198 into threaded recesses 200 in the outer shell 162.
  • the auxiliary iin construction 184 is made of a high heat-conductive material, such as aluminum or copper. It will be seen that intimate engagement between the auxiliary fins 184 and the Outer shell 162 may be obtained by exerting pressure between the soft contact surface 192 and the structural members 168 of the outer shell 162, thereby insuring eicient pickup of heat from the cask 160.
  • the auxiliary n construction 146 and 184 is made up of high-conductive material, such as copper or aluminum and is removable from the Cask 10 before the Cask is lowered into the loading or unloading pool.
  • These loading pools may contain radioactive particles that would lodge into the space between closely spaced tins and that would be extremely diilicult to clean from the fins. Therefore, by providing removable fins, such a contamination problem may be avoided.
  • An apparatus for transporting exothermic radioactive material comprising a cask, said caslr having walls constructed of an outer shell and an inner shell spaced from said outer shell, a radiation-shielding ller between said outer and inner shells, said inner shell including a plurality of heat-conductive fins for dissipating heat through said cask wall, said outer shell having a iinlike construction, said fin-like construction including a plurality of 'U-shaped fins spaced apart by high heatconductive strips radially aligned with relation to the center line of said cask, and an auxiliary heat-conductive fin assembly removably mounted on said outer shell, whereby a large surface is exposed to the ambient atmosphere for dissipating heat from the cask.
  • An apparatus for transporting exothermic radioactive material comprising a cask, said cask having Walls constructed of an outer shell and an inner shell spaced from said outer shell, a radiation-shielding ller between said outer and inner shells, said outer and inner shells having a heat-conductive fin-like construction for dissipating heat from said cask, and an auxiliary heat-conductive iin assembly removably mounted externally on said outer shell, whereby a large heat-conductive surface is exposed to the ambient atmosphere.
  • An apparatus for transporting exothermic radioactive material comprising a cask, said cask having walls constructed of an outer shell and an inner shell spaced from said outer shell, a radiation-shielding filler between said outer and inner shells, said outer and inner shells having a heat-conductive fin-like construction for dissipating heat from said cask, said outer shell having a plurality of radially-aligned ns and a plurality of radially-aligned conducting strips, each being intersticed between said fins and associated with the radiation-shielding iiller, said inner shell being constructed of an internal liner and a plurality of longitudinally-extending fluid conducting pipes mounted radially around said liner and in spaced relation from each other, a removable lid for said cask, means for fastening said lid to said cask, and structural supports mounted on said outer shell for carrying said cask,
  • An apparatus for transporting exothermic radioactive material comprising a cask, said cask having Walls constructed of an outer shell and an inner shell spaced from said outer shell, a radiation-shielding ller between said outer and inner shells, said outer and inner shells having a heat-conductive iin-like construction for dissipating heat from said cask, said outer shell having a plurality of radially-aligned fins each of U-shaped construction and a plurality of radially-aligned conducting strips, each being intersticed between said fins and associated with said radiation-shielding filler, said inner shell being constructed of an internal liner and a plurality of longitudinally-extending fluid conducting pipes mounted radially around said liner and in spaced relation from each other, said pipes being interconnected at their upper and lower extremities, a removable lid for said cask, means for fastening said lid to said cask, and structural supports mounted on said outer shell for carrying said cask.
  • An apparatus for transporting exothermic radioactive material comprising a cask, said Cask having walls constructed of an outer shell and an inner shell spaced from said outer shell, a radiation-shielding iiller between said outer and inner shells, said outer and inner shells having a heat-conductive iin-like construction for dissipating heat from said cask, said outer shell having a plurality of radially-aligned tins each of V-shaped construction and a plurality of radially-aligned conducting strips, each being intersticed between said ns and associated with said radiation-shielding filler, said conducting strips being lead-bonded to said fins, said inner shell being constructed of an internal liner and a plurality of longitudinally-extending fluid conducting pipes mounted radially around said liner and in spaced relation from each other, a removable lid for said cask, means for fastening said lid to said cask, and structural supports mounted on said outer shell for carrying said cask.
  • An apparatus for transporting exothermic radioactive material comprising a cask, said cask having walls constructed of an outer shell and an inner shell spaced from said outer shell, a radiation-shielding filler between said outer and inner shells, said outer and inner shells having a heat-conductive iin-like construction for dissipating heat from said cask, said outer shell having a plurality of radially-aligned fins spaced apart by radially-aligned conducting strips brazed thereto, said conducting strips being associated with the radiation-shielding ller, and a plurality of Wedge-receiving fins intersticed between groups of said ns, said inner shell having an internal liner and a plurality of internal fins brazed thereto and spaced apart from each other, a removable lid for said cask, means for fastening said lid to said cask, structural supports mounted on said outer shell for carrying said cask, and auxiliary heat-conducting iin assemblies adapted to be removably mounted
  • An apparatus for transporting exothermic radioactive material comprising a cask, said cask having walls constructed of an outer shell and an inner shell spaced from said outer shell, a radiation-shielding filler between said outer and inner shells, said outer and inner shells having a heat-conductive fin-like construction for dissipating heat from said cask, said outer shell having a plurality of radially-aligned lins each of U-shaped construction spaced apart by radially-aligned conducting strips brazed thereto and associated with the radiationshielding filler, and a plurality of wedge-receiving iins each of H-shaped construction intersticed between groups of said fins, said inner shell having an internal liner and a plurality of internal fins brazed thereto and spaced-apart from each other, a removable lidmfwor said cask, means for fastening said lid to said caslstructral supports mounted on said outer shell for carrying said cask, and auxiliary heat-conducting fin assemblies
  • An apparatus for transporting exothermic radioactive material comprising a cask, said cask having walls constructed of an outer shell and an inner shell spaced from said outer shell, a radiation-shielding liller between said outer and inner shells, said outer and inner shells having a heat-conductive fin-like construction for dissipating heat from said cask, said outer shell having a plurality of radially-aligned iins spaced apart from each other, structural blocks spacing said ns, radially-aligned conducting strips extending inwardly from said structural blocks into said radiation-shielding filler, said inner shell having an internal liner and a plurality of internal fins secured thereto and spaced apart from each other, a removable lid for said cask, means for fastening said lid to said cask, structural supports mounted on said outer shell for carrying said cask, and auxiliary heat-conducting fin assemblies adapted to be removably mounted externally on said outer shell,y each auxiliary n assembly having a supporting member, iin
  • An apparatus for transporting exothermic radioactive material comprising a cask, having an outer shell and an inner shell, high radiation-shielding material between said outer and inner shells, said outer shell having a iin-like construction, said iin-like construction including a plurality of 'U-shaped fins joined together at their meeting edges with radially-aligned conducting strips having an inner portion associated with said high radiation-shielding material, whereby one surface is exposed to the ambient atmosphere and the other surface is exposed to the shielding material.
  • An apparatus for transporting exothermic radioactive material comprising a cask, said cask having walls constructed of an outer shell and an inner shell spaced from said outer shell, a radiation-shielding filler between said outer and inner shells, said outer and inner shells having a heat-conductive 1in-like construction for dissipating heat 1from said Cask, said outer shell having a plurality of radially-aligned ns each of U-shaped construction spaced apart by radially-aligned conducting strips brazed thereto, said conducting strips associated at their inner edges with the radiation-shielding ller, a plurality of wedge-receiving ns intersticed between groups of said fins, said inner shell having an internal liner and a plurality of internal ns connected thereto and spaced apart from each other, said internal ns being directed towards said Wedge-receiving tins, a removable lid for said Cask, means for fastening said lid to said Cask,

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Description

op@ humains Dec. 3, 1963 J. w. ALLEN 3,113,215
CASK CONSTRUCTION FOR RADIOACTIVE MATERIAL Filed Feb. 27, 1961 4 Sheets-Sheet 1 ZQ/ 7p I E d l w g m 5/ 1 /f'i "'J 74]/ i I610 ,6 kx
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Dec. 3, 1963 J. W. ALLEN CASK CONSTRUCTION FOR RADIOACTIVE MATERIAL Filed Feb. 2'?, 19t-1 4 Sheets-Sheet 2 IN V EN TOR.
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Dec. 3, 1963 J. w. ALLEN 3,113,215
CASK CONSTRUCTION FOR RADIOACTIVE MATERIAL Filed Feb. 27, 1961 4 Sheets-Sheet 3 IN V EN TOR.
DeC- 3 1963 J. w. ALLEN 3,113,215
CASK CONSTRUCTION FOR RADIOACTIVE MATERIAL Filed Feb.' 27, 1961 4 Sheets-Sheet 4 United States Patent 3,133,215. CASK CNSRUCTEN EGR RADIACTHVE MATERiAL lohn W. Alien, Hinsdaie, lil., assigner to Stanray Corporation, Chicago, lli., a corporation of Delaware Fiied Feb. 27, 1961, Ser. No. 92,038 1t? Claims. (Cl. 25h-403) This invention relates to casks for transporting radioactive materials; more particularly it relates to casks or containers of minimal dimensions and weight, yet having high strength for transporting intensely radioactive matreials which are exothermic and which may encounter temperatures from heat generated internally of several hundred degrees Fahrenheit during transport. More specifically the invention relates to a cask, suitable for the shipment of intensely radioactive materials which may be exothermic, constructed so as to have very high thermal conductivity to condut the heat from said casks to the ambient air as rapidly as possible.
Such casks may be carried in a truck or on a fiat car and transported to its destination through populated areas and it is necessary that the cask provide ample shielding to prevent exposure to the general public of radiation and heat burns, and yet provide rapid thermal conductivity to release the heat generated within the container. Hence it is an object of the present invention to provide a cask comprising a composite structure incorporating the best features of various materials for the construction of a suitable radiation shielding container, of minimal weight and high thermal conductivity and suitable for transporting intensely radioactive materials safely.
The invention comprises briefly a minimum dimension container adapted for transporting intensely radioactive materials, having inner and outer shells in spaced relation, high radiation-shielding material between the shells, the shells being constructed of finned sections to provide high thermal conductivity, the outer shell having attached banks of fins to provide additional thermal conductivity, and the radiation being attenuated by passing transversely through the high density shielding material members or the finned sections. The outer liner consists of bent plates welded together to give a fin surface for heat dissipation to the surrounding air. The space between the outstanding lianges is filled with high heat-conductive material to improve the eiciency of the tins. The space is lled with lead, as the main portion of the lead inside the liner is poured. A strip of aluminum or copper, brazed to the liner material, or held in place by the lead, is used to improve the heat conduction. The liner is constructed of stainless steel to provide a non-corrosive surface which is easy to decontaminate.
Referring now to the accompanying drawings forming part of this application and wherein like reference characters indicate like parts:
FIGURE l is a central longitudinal cross sectional view of the preferred form of Cask.
FIGURE 2 is a transverse sectional view through a portion of the cask of FIGURE l, showing a high conductive strip brazed to the fin material.
FIGURE 3 is a fragmental view, similar to FEGURE 2, showing the conductive strip lead-bonded to the fins.
FIGURE 4 is a side elevational view of a portion of a Cask showing a modified auxiliary iin arrangement.
FIGURE 5 is a horizontal sectional view through the Cask of FIGURE 4.
FIGURE 6 is a partial cross section through a cask having auxiliary cooling fins of slightly different arrangement.
Referring now more particularly to the drawings, FIG- URES l and 2 illustrate a preferred construction of a cask indicated generally by the reference 10. The cask ICC or container llt) comprises an outer shell 12 and an inner shell 14 in spaced relation from said outer shell. The cask may be of any suitable configuration although a cylindrical configuration is illustrated in this embodiment.
The outer shell i2 is constructed of a plurality of ns i6 each extending from the upper end 18 of the cask to the bottom end 20 and being of a U-shaped construction with legs 22 extending radially with relation to the center line 212- of the cask 10. The fins 16 are spaced apart from each other by means of conducting strips 26. The outer extremities 28, both of the fin legs 22 and of the strips 26, are joined together in any suitable manner such as by the welds 30 so as to present a corrugated or fin surface construction to the outer shell 12.
The inner shell 14 is constructed of a liner 32 to which are attached a plurality of longitudinally-extending fluid conducting pipes 34 mounted radially around the liner and in spaced relation to each other. The pipes 34 are interconnected at their upper and lower extremities 36, 3S and extend from upper and lower annular pipes 46, 42.
The outer and inner shells 12, 14 are spaced apart by means of structural braces 44 and a suitable filler i6 which may be poured into the space 43 formed between the shells. The braces 44 are spaced from the internal liner 32 by means of suitable supporting structure 56 and are connected to the outer shell l2 by suitable welding 52 to the distorted ns 54. Secondary fins S6, 58 may be mounted on the braces 44 to aid in longitudinal heat conduction.
A removable lid et) is provided at the top of the cask 10, which is always carried in a vertical position, as shown in FIGURE l. The lid 69 is constructed of an outer head 62 and an inner head 64, the fatter being of a hollow construction and .filled with a suitable filler 66 similar to the filler 46 between the outer and inner shells l2, 14 of the cask it). The outer head 62 and the inner head 64 of the lid 6) are secured together by means of suitable bolts 63. The lid 69 may be removably fastened to the top of the cask l0 by means of bolts 70 and seats on a recessed contour which provides a pressure seal between the cask walls and the lid 60. In this regard, the outer head 6E seats on a flange '72 and the inner head 64 seats on a step flange 74. Suitable gaskets '76, constructed of resilient material, are provided in recesses 78 in the outer head 62, which gaskets 7d engage the flange 72. The lid 6i) may be provided with a conventional pressure release check valve (not shown), if so desired, having an adjustable pressure release mechanism connecting the interior of the cask with the ambient atmosphere, through an indirect channel to prevent t e escape of nnattenuated radiation, when the pressure within the Cask exceeds the preset release valve.
In order to increase the heat dissipation of the cask, a natural convection liquid circulating system is provided and comprises a plurality of pipes 3d positioned within the wall of the cask 1G and next to thc internal liner 32. The pipes 34 are interconnected by means of annular pipes dii, 42 and communicate by way of conduits 80, 82 to an external series of pipes (not shown) for dissipating the heat to the ambient atmosphere. This circulating system may be regulated by means of valves 84, 86 located externally of the outer shell 12 on the conduits Si), $2. When the liquid circulating cooling system is not in operation, the pipes 34 act as internal fins for transferring heat from the internal liner 32 to the filler i6 and thence to the intermediate fins I6 of the outer shell i2 and to the ambient atmosphere.
Structural supports for the cask are supplied by external annular ring construction 88 which comprises a plurality of annular members 90, each having an internal wall 92, and an external wall 94, spaced from the internal wall 92 by means of ribs 95. Supported trunnions 93 for carry- 3 ing the cask extend through the external ring construction 88. Conduits 80, 82 and their valves 84, 86 are located within the structure of the external ring construction 88 for protection from possible damaging Contact during transportation of the Cask 18, as shown in FIG- URE 1.
The outer shell 12 is preferably made of a strong structural material to impart strength to the casl; 10. The fins 16 are made of a low conductive material, such as stainless steel, while the conductnig strips 26 are made of a high-conductive material, such as copper or aluminum. The conductivity of stainless steel is only about nine B.t.u. per hour per degree Fahrenheit per foot, while the conductivity of aluminum is one hundred twenty, and copper is two hundred twenty. The internal liner 32 is composed of stainless steel; and the pipes 34, the annular tubes 48, 42 and the conduits 80, 82 are made of highconduetive material such as copper. The fillers 46, 66 are composed of high radiation-shielding material, such as lead, which may be poured between the outer and inner shells 12, 14 and into the hollow inner head 64 of the lid 68. The pipes 34 are brazed to the liner 32, as are the conducting strips 26 to the iins 16.
It will be seen that the fin construction 16 of the outer shell 12 presents a large corrugated surface to the lead iiller 46. This is necessary since it is impractical to obtain a 100% true metallic bond between the lead filler 46 and the stainless steel fins 16. The resulting air gap between the lead and the steel presents a heat barrier which is reduced in proportion to the arca of this gap. The iin construction 16, illustrated in FGURES l and 2, provides a large area both to the air gap between the lead and the steel and also to the ambient atmosphere. The ns 16 have a rounded configuration which is smooth and devoid of rough welds and, therefore, facilitates cleaning during decontamination. The welds 38, at the outer extremities 28 of the fins 16 and conducting strips 26, do not transfer heat, so do not require full fusion welding. These wclds are also much more accessible during fabrication of the Cask for the Welding operation and are ground smooth to present an easy surface to clean. The corrugated 1in construction 16 also provides expansion capabilities to provide for expansion of the lead filler 46 due to its increased temperature and high coecient of expansion.
A modification of my invention for Cask construction for transporting thermally hot intensely radioactive material is illustrated in FGURE 3 in which the caslr is shown generally by the reference 188 and is comprised of an internal shell (not shown), similar to that illustrated in FIGURES 1 and 2, and an external shell 102 having a plurality of radially aligned V-shaped fins 1114 spaced apart by means of conducting strips 106. The fins 104 and conducting strips 166 are outwardly joined together by means of suitable Welds 108.
A third embodiment of my invention is illustrated in FIGURES 4 and 5, in which the caslt is shown generally by the reference 110 and is comprised of outer and inner shells 112, 114 in spaced relation from each other. The outer shell 112 is constructed of a plurality of radially aligned U-shaped fins 116 spaced apart by means of conducting strips 118, said tins 116 and conducting strips 118 being outwardly joined together by means of suitable welds 128. Intersticed between groups of the fins 116 and conducting strips 118 are a plurality of H-shaped wedge-receiving tins 122 having a radially outwardlyfacing recess 124, formed between the radially outwardlyextending legs 126, 128, and an inwardly-oriented recess 130, formed between the inwardly-extending askew legs 132, 134. The legs 126, 132 and 128, 134 of the hns 122 are spaced apart by means of post 136. These conducting ns 122 are internally seated within and brazed to a liner 138 which forms an RVi-shaped extension of the fins 116. The inner shell 114 is constructed of a liner 148 t0 which are brazed a plurality of radially-aligned internal fins 142, which have legs 144 directed to dissipate heat toward the recess of the conducting fins 122 of the outer shell 112. Adapted to seat within the recesses 124 of the wedge-receiving tins 122 are a series of external fins 146 each constructed of a supporting wedge member 148 from which extend a plurality of closely-spaced fin blades 15). The auxiliary iins 146 may be removably mounted to the cask 11G by means of suitable bolts 152. Between the outer and inner shells 112, 114 is poured a suitable radiation-shielding iiller 154. A removable lid 156 is mounted on the top of the cask 110 by means of suitable bolts 158.
In this embodiment, the internal liner and outer shell fins 116 are constructed of stainless steel, the internal fins 142, conducting strips 118 and conducting ns 122 are made of copper, and the auxiliary tins 146 are made of aluminum, While the filler 154 is lead.
A fourth embodiment of my invention is illustrated in FIGURE 6, in which the cask is shown generally by the reference 168. The cask 1611 is hexagonal in configuration and is comprised of an outer shell 162 spaced apart from an inner shell 164. The outer shell 162 is constructed of a plurality of U-shaped fins 166, made of a low-conductive material, such as stainless steel, said ns 166 being spaced apart by means of structural blocks 168, also made of stainless steel. Imbedded in the structural blocks 168 are inwardly-extending conducting strips 170, made of a high-conductive material, such as copper. The innermost extremities 172 of the conducting strips 170 are structurally supported and brazed to braces 174, also made of a high heat-conductive material, such as copper. The inner shell 164 is constructed of an internal liner 176, made of a low-conductive material such as stainless steel, to which is attached a plurality of internal tins 178 of high heat-conductive material, such as copper. The outer extremities 186 of the internal ins 178 are structurally supported by and brazed to the braces 1'74. A suitable high radiation-shielding material, such as lead, is poured into the space between the outer and inner shells 162, 164 to form a filler 182. Auxiliary removable fins 184 are mounted externally on the Cask 160, and each comprises a supporting member 186 from which extends a plurality of closely-spaced iin blades 188. The inner end 190 of the supporting members 186 is mounted in a flat surface contact 192, made of a soft material, such as soft copper, for intimate contact with the structural blocks 168 0f the outer Shell 162. The outer end 194 of the supporting members 186 is mounted in a frame 196 which is bolted by means of suitable bolts 198 into threaded recesses 200 in the outer shell 162. The auxiliary iin construction 184 is made of a high heat-conductive material, such as aluminum or copper. It will be seen that intimate engagement between the auxiliary fins 184 and the Outer shell 162 may be obtained by exerting pressure between the soft contact surface 192 and the structural members 168 of the outer shell 162, thereby insuring eicient pickup of heat from the cask 160.
The auxiliary n construction 146 and 184 is made up of high-conductive material, such as copper or aluminum and is removable from the Cask 10 before the Cask is lowered into the loading or unloading pool. These loading pools may contain radioactive particles that would lodge into the space between closely spaced tins and that would be extremely diilicult to clean from the fins. Therefore, by providing removable fins, such a contamination problem may be avoided.
The foregoing specification, specific examples and descriptions of my invention and the methods of utilizing it are intended as illustrative of the invention, the scope of which is limited only by the following claims.
What is claimed is:
1. An apparatus for transporting exothermic radioactive material comprising a cask, said caslr having walls constructed of an outer shell and an inner shell spaced from said outer shell, a radiation-shielding ller between said outer and inner shells, said inner shell including a plurality of heat-conductive fins for dissipating heat through said cask wall, said outer shell having a iinlike construction, said fin-like construction including a plurality of 'U-shaped fins spaced apart by high heatconductive strips radially aligned with relation to the center line of said cask, and an auxiliary heat-conductive fin assembly removably mounted on said outer shell, whereby a large surface is exposed to the ambient atmosphere for dissipating heat from the cask.
2. An apparatus for transporting exothermic radioactive material comprising a cask, said cask having Walls constructed of an outer shell and an inner shell spaced from said outer shell, a radiation-shielding ller between said outer and inner shells, said outer and inner shells having a heat-conductive fin-like construction for dissipating heat from said cask, and an auxiliary heat-conductive iin assembly removably mounted externally on said outer shell, whereby a large heat-conductive surface is exposed to the ambient atmosphere.
3. An apparatus for transporting exothermic radioactive material comprising a cask, said cask having walls constructed of an outer shell and an inner shell spaced from said outer shell, a radiation-shielding filler between said outer and inner shells, said outer and inner shells having a heat-conductive fin-like construction for dissipating heat from said cask, said outer shell having a plurality of radially-aligned ns and a plurality of radially-aligned conducting strips, each being intersticed between said fins and associated with the radiation-shielding iiller, said inner shell being constructed of an internal liner and a plurality of longitudinally-extending fluid conducting pipes mounted radially around said liner and in spaced relation from each other, a removable lid for said cask, means for fastening said lid to said cask, and structural supports mounted on said outer shell for carrying said cask,
4. An apparatus for transporting exothermic radioactive material comprising a cask, said cask having Walls constructed of an outer shell and an inner shell spaced from said outer shell, a radiation-shielding ller between said outer and inner shells, said outer and inner shells having a heat-conductive iin-like construction for dissipating heat from said cask, said outer shell having a plurality of radially-aligned fins each of U-shaped construction and a plurality of radially-aligned conducting strips, each being intersticed between said fins and associated with said radiation-shielding filler, said inner shell being constructed of an internal liner and a plurality of longitudinally-extending fluid conducting pipes mounted radially around said liner and in spaced relation from each other, said pipes being interconnected at their upper and lower extremities, a removable lid for said cask, means for fastening said lid to said cask, and structural supports mounted on said outer shell for carrying said cask.
5. An apparatus for transporting exothermic radioactive material comprising a cask, said Cask having walls constructed of an outer shell and an inner shell spaced from said outer shell, a radiation-shielding iiller between said outer and inner shells, said outer and inner shells having a heat-conductive iin-like construction for dissipating heat from said cask, said outer shell having a plurality of radially-aligned tins each of V-shaped construction and a plurality of radially-aligned conducting strips, each being intersticed between said ns and associated with said radiation-shielding filler, said conducting strips being lead-bonded to said fins, said inner shell being constructed of an internal liner and a plurality of longitudinally-extending fluid conducting pipes mounted radially around said liner and in spaced relation from each other, a removable lid for said cask, means for fastening said lid to said cask, and structural supports mounted on said outer shell for carrying said cask.
6. An apparatus for transporting exothermic radioactive material comprising a cask, said cask having walls constructed of an outer shell and an inner shell spaced from said outer shell, a radiation-shielding filler between said outer and inner shells, said outer and inner shells having a heat-conductive iin-like construction for dissipating heat from said cask, said outer shell having a plurality of radially-aligned fins spaced apart by radially-aligned conducting strips brazed thereto, said conducting strips being associated with the radiation-shielding ller, and a plurality of Wedge-receiving fins intersticed between groups of said ns, said inner shell having an internal liner and a plurality of internal fins brazed thereto and spaced apart from each other, a removable lid for said cask, means for fastening said lid to said cask, structural supports mounted on said outer shell for carrying said cask, and auxiliary heat-conducting iin assemblies adapted to be removably mounted externally on said outer shell, each auxiliary fin assembly having wedge members engaging said wedge-receiving ns.
7. An apparatus for transporting exothermic radioactive material comprising a cask, said cask having walls constructed of an outer shell and an inner shell spaced from said outer shell, a radiation-shielding filler between said outer and inner shells, said outer and inner shells having a heat-conductive fin-like construction for dissipating heat from said cask, said outer shell having a plurality of radially-aligned lins each of U-shaped construction spaced apart by radially-aligned conducting strips brazed thereto and associated with the radiationshielding filler, and a plurality of wedge-receiving iins each of H-shaped construction intersticed between groups of said fins, said inner shell having an internal liner and a plurality of internal fins brazed thereto and spaced-apart from each other, a removable lidmfwor said cask, means for fastening said lid to said caslstructral supports mounted on said outer shell for carrying said cask, and auxiliary heat-conducting fin assemblies adapted to be removably mounted externally on said outer shell, each auxiliary iin assembly having wedge members engaging said wedge-receiving fins.
8. An apparatus for transporting exothermic radioactive material comprising a cask, said cask having walls constructed of an outer shell and an inner shell spaced from said outer shell, a radiation-shielding liller between said outer and inner shells, said outer and inner shells having a heat-conductive fin-like construction for dissipating heat from said cask, said outer shell having a plurality of radially-aligned iins spaced apart from each other, structural blocks spacing said ns, radially-aligned conducting strips extending inwardly from said structural blocks into said radiation-shielding filler, said inner shell having an internal liner and a plurality of internal fins secured thereto and spaced apart from each other, a removable lid for said cask, means for fastening said lid to said cask, structural supports mounted on said outer shell for carrying said cask, and auxiliary heat-conducting fin assemblies adapted to be removably mounted externally on said outer shell,y each auxiliary n assembly having a supporting member, iin blades extending therefrom, a flat surface contact and means for biasing said at surface contact into intimate engagement with said structural block of said outer shell.
9. An apparatus for transporting exothermic radioactive material comprising a cask, having an outer shell and an inner shell, high radiation-shielding material between said outer and inner shells, said outer shell having a iin-like construction, said iin-like construction including a plurality of 'U-shaped fins joined together at their meeting edges with radially-aligned conducting strips having an inner portion associated with said high radiation-shielding material, whereby one surface is exposed to the ambient atmosphere and the other surface is exposed to the shielding material.
l0. An apparatus for transporting exothermic radioactive material comprising a cask, said cask having walls constructed of an outer shell and an inner shell spaced from said outer shell, a radiation-shielding filler between said outer and inner shells, said outer and inner shells having a heat-conductive 1in-like construction for dissipating heat 1from said Cask, said outer shell having a plurality of radially-aligned ns each of U-shaped construction spaced apart by radially-aligned conducting strips brazed thereto, said conducting strips associated at their inner edges with the radiation-shielding ller, a plurality of wedge-receiving ns intersticed between groups of said fins, said inner shell having an internal liner and a plurality of internal ns connected thereto and spaced apart from each other, said internal ns being directed towards said Wedge-receiving tins, a removable lid for said Cask, means for fastening said lid to said Cask, means associated With said outer shell for carrying 5 fins.
References Cited in the tile of this patent UNITED STATES PATENTS 2,600,390 Boyer June 17, 1952 10 2,968,734 Yeomans Ian. 17, 1961 3,005,105 Lusk Oct. 17, 1961 FOREIGN PATENTS 613,974 Canada Feb. 7, 1961

Claims (1)

1. AN APPARATUS FOR TRANSPORTING EXOTHERMIC RADIOACTIVE MATERIAL COMPRISING A CASK, SAID CASK HAVING WALLS CONSTRUCTED OF AN OUTER SHELL AND AN INNER SHELL SPACED FROM SAID OUTER SHELL, A RADIATION-SHIELDING FILLER BETWEEN SAID OUTER AND INNER SHELLS, SAID INNER SHELL INCLUDING A PLURALITY OF HEAT-CONDUCTIVE FINS FOR DISSIPATING HEAT THROUGH SAID CASK WALL, SAID OUTER SHELL HAVING A FINLIKE CONSTRUCTION, SAID FIN-LIKE CONSTRUCTION INCLUDING A PLURALITY OF U-SHAPED FINS SPACED APART BY HIGH HEATCONDUCTIVE STRIPS RADIALLY ALIGNED WITH RELATION TO THE CENTER LINE OF SAID CASK, AND AN AUXILIARY HEAT-CONDUCTIVE FIN ASSEMBLY REMOVABLY MOUNTED ON SAID OUTER SHELL, WHEREBY A LARGE SURFACE IS EXPOSED TO THE AMBIENT ATMOSPHERE FOR DISSIPATING HEAT FROM THE CASK.
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Cited By (36)

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US3363100A (en) * 1963-05-27 1968-01-09 Franklin Gno Corp Radiation detection system for missile scoring
US3414727A (en) * 1965-04-26 1968-12-03 Nat Lead Co Shipping container for radioactive material including safety shield means
US3466662A (en) * 1964-10-21 1969-09-09 Lyonnaise De Plomberie Ind Soc Fireproof shielded containers for radioactive materials
US3575601A (en) * 1965-05-07 1971-04-20 Atomic Energy Authority Uk Transport containers for radioactive materials
FR2073318A1 (en) * 1969-11-03 1971-10-01 Kernforschung Gmbh Ges Fuer
FR2085189A1 (en) * 1970-01-14 1971-12-24 Transnucleaire Storage and transport container for a - radioactive materials
US3669299A (en) * 1970-10-30 1972-06-13 Uniroyal Inc Mechanical and thermal damage protection and insulation materials usable therefor
DE2358979A1 (en) * 1972-11-28 1974-05-30 Robatel Slpi CONTAINER FOR WRAPPING AND TRANSPORTING RADIOACTIVE MATERIALS
DE2065863A1 (en) * 1969-08-13 1976-09-23 Transnucleaire Transportation container for radioactive prods. - has cooling fins embedded in aluminous cement outside container wall
DE2040348B2 (en) 1969-08-13 1976-10-21 Ausscheidung in: 20 65 863 Transnucleaire, Societe pour les Transports de l'Industrie Nucleaire, Paris CONTAINER FOR STORAGE AND TRANSPORTATION OF RADIOACTIVE MATERIALS
USRE29876E (en) * 1971-01-26 1979-01-02 Container for transporting radioactive materials
FR2411472A1 (en) * 1977-12-09 1979-07-06 Steag Kernenergie Gmbh PROTECTIVE CONTAINER INTENDED FOR TRANSPORT AND / OR STORAGE OF RADIO-ACTIVE WASTE
US4197467A (en) * 1977-12-16 1980-04-08 N L Industries, Inc. Dry containment of radioactive materials
FR2448768A1 (en) * 1979-02-10 1980-09-05 Nuklear Service Gmbh Gns CONTAINER FOR THE TRANSPORT AND / OR STORAGE OF RADIOACTIVE WASTE
US4234798A (en) * 1977-09-07 1980-11-18 Steag Kernenergie Gmbh Transport and storage receptacle for radioactive waste
DE2952168A1 (en) * 1979-12-22 1981-07-02 Transnuklear Gmbh, 6450 Hanau Transport and storage vessel for irradiated fuel elements - has firmly pressed inner liner giving good thermal contact
US4288698A (en) * 1978-12-29 1981-09-08 GNS Gesellschaft fur Nuklear-Service mbH Transport and storage vessel for radioactive materials
US4291536A (en) * 1977-04-22 1981-09-29 Messier S.A. Apparatus enabling the storage of radioactive wastes and the recovery of the extraneous heat emitted thereby, and a storage element for incorporation in such apparatus
US4308460A (en) * 1980-07-31 1981-12-29 The United States Of America As Represented By The United States Department Of Energy Storage containers for radioactive material
DE3033083A1 (en) * 1980-09-03 1982-04-01 Anton J. 7302 Ostfildern Vox Transport and storage container esp. for irradiated fuel elements - has detachable heat dissipation jackets pref. of aluminium
US4330711A (en) * 1979-04-14 1982-05-18 Stefan Ahner Container combination for the transportation and storage of radioactive waste especially nuclear reactor fuel elements
DE2066133C2 (en) * 1969-08-13 1983-07-28 Transnucléaire, Société pour les Transports de l'Industrie Nucléaire, Paris Containers for the storage and transport of radioactive materials
EP0143398A2 (en) * 1983-11-29 1985-06-05 Alkem Gmbh Container, in particular for radioactive substances
FR2572213A1 (en) * 1984-10-22 1986-04-25 Westinghouse Electric Corp OUT OF STOCK NUCLEAR FUEL STORAGE CASTLE
US4634875A (en) * 1983-01-20 1987-01-06 Kernforschungsanlage Julich Gesellschaft Mit Beschrankter Haftung Transitory storage for highly-radioactive wastes
EP0842870A1 (en) * 1996-10-28 1998-05-20 Forschungszentrum Karlsruhe GmbH Waste receptacle for hazardous materials with a lid closure according to the double lid principle
US20040125906A1 (en) * 2002-11-09 2004-07-01 Gnb Gesellschaft Fur Nuklear-Behalter Mbh Container for heat-generating radioactive elements
EP1622169A1 (en) * 2004-07-31 2006-02-01 GNS Gesellschaft für Nuklear-Service mbH Transport container for radioactive elements
US20060219960A1 (en) * 2003-01-31 2006-10-05 Kabushiki Kaisha Kobe Seiko Sho Concrete cask and method for manufacturing thereof
US20060291609A1 (en) * 2005-06-23 2006-12-28 Nac International, Inc. Apparatuses and methods for mechanical shielding and cooling
US20080137794A1 (en) * 2005-12-01 2008-06-12 Nac International, Inc. Systems and methods for loading and transferring spent nuclear fuel
US20110091003A1 (en) * 2006-01-25 2011-04-21 Commissariat A L'energie Atomique Method and device for sealing a canister loaded with irradiated nuclear fuel in a cooling pond
US9793021B2 (en) 2014-01-22 2017-10-17 Nac International Inc. Transfer cask system having passive cooling
US10032533B2 (en) 2013-10-02 2018-07-24 Nac International Inc. Systems and methods for transferring spent nuclear fuel from wet storage to dry storage
US10770194B2 (en) * 2016-08-10 2020-09-08 Jonathan Bright Nuclear fuel storage cask
US10923241B2 (en) * 2016-09-30 2021-02-16 Hitachi Zosen Corporation Concrete cask

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US2968734A (en) * 1956-01-06 1961-01-17 Martin Co Device for the exposure of fluid to radiation
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Cited By (44)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3363100A (en) * 1963-05-27 1968-01-09 Franklin Gno Corp Radiation detection system for missile scoring
US3466662A (en) * 1964-10-21 1969-09-09 Lyonnaise De Plomberie Ind Soc Fireproof shielded containers for radioactive materials
US3414727A (en) * 1965-04-26 1968-12-03 Nat Lead Co Shipping container for radioactive material including safety shield means
US3575601A (en) * 1965-05-07 1971-04-20 Atomic Energy Authority Uk Transport containers for radioactive materials
DE2040348B2 (en) 1969-08-13 1976-10-21 Ausscheidung in: 20 65 863 Transnucleaire, Societe pour les Transports de l'Industrie Nucleaire, Paris CONTAINER FOR STORAGE AND TRANSPORTATION OF RADIOACTIVE MATERIALS
DE2065863A1 (en) * 1969-08-13 1976-09-23 Transnucleaire Transportation container for radioactive prods. - has cooling fins embedded in aluminous cement outside container wall
DE2066133C2 (en) * 1969-08-13 1983-07-28 Transnucléaire, Société pour les Transports de l'Industrie Nucléaire, Paris Containers for the storage and transport of radioactive materials
FR2073318A1 (en) * 1969-11-03 1971-10-01 Kernforschung Gmbh Ges Fuer
FR2085189A1 (en) * 1970-01-14 1971-12-24 Transnucleaire Storage and transport container for a - radioactive materials
US3669299A (en) * 1970-10-30 1972-06-13 Uniroyal Inc Mechanical and thermal damage protection and insulation materials usable therefor
USRE29876E (en) * 1971-01-26 1979-01-02 Container for transporting radioactive materials
DE2358979A1 (en) * 1972-11-28 1974-05-30 Robatel Slpi CONTAINER FOR WRAPPING AND TRANSPORTING RADIOACTIVE MATERIALS
US4291536A (en) * 1977-04-22 1981-09-29 Messier S.A. Apparatus enabling the storage of radioactive wastes and the recovery of the extraneous heat emitted thereby, and a storage element for incorporation in such apparatus
US4234798A (en) * 1977-09-07 1980-11-18 Steag Kernenergie Gmbh Transport and storage receptacle for radioactive waste
FR2411472A1 (en) * 1977-12-09 1979-07-06 Steag Kernenergie Gmbh PROTECTIVE CONTAINER INTENDED FOR TRANSPORT AND / OR STORAGE OF RADIO-ACTIVE WASTE
US4278892A (en) * 1977-12-09 1981-07-14 Steag Kernergie Gmbh Radioactivity-shielding transport or storage receptacle for radioactive wastes
US4197467A (en) * 1977-12-16 1980-04-08 N L Industries, Inc. Dry containment of radioactive materials
US4288698A (en) * 1978-12-29 1981-09-08 GNS Gesellschaft fur Nuklear-Service mbH Transport and storage vessel for radioactive materials
FR2448768A1 (en) * 1979-02-10 1980-09-05 Nuklear Service Gmbh Gns CONTAINER FOR THE TRANSPORT AND / OR STORAGE OF RADIOACTIVE WASTE
US4330711A (en) * 1979-04-14 1982-05-18 Stefan Ahner Container combination for the transportation and storage of radioactive waste especially nuclear reactor fuel elements
DE2952168A1 (en) * 1979-12-22 1981-07-02 Transnuklear Gmbh, 6450 Hanau Transport and storage vessel for irradiated fuel elements - has firmly pressed inner liner giving good thermal contact
US4308460A (en) * 1980-07-31 1981-12-29 The United States Of America As Represented By The United States Department Of Energy Storage containers for radioactive material
DE3033083A1 (en) * 1980-09-03 1982-04-01 Anton J. 7302 Ostfildern Vox Transport and storage container esp. for irradiated fuel elements - has detachable heat dissipation jackets pref. of aluminium
US4634875A (en) * 1983-01-20 1987-01-06 Kernforschungsanlage Julich Gesellschaft Mit Beschrankter Haftung Transitory storage for highly-radioactive wastes
EP0143398A2 (en) * 1983-11-29 1985-06-05 Alkem Gmbh Container, in particular for radioactive substances
EP0143398A3 (en) * 1983-11-29 1985-07-17 Alkem Gmbh Container, in particular for radioactive substances
FR2572213A1 (en) * 1984-10-22 1986-04-25 Westinghouse Electric Corp OUT OF STOCK NUCLEAR FUEL STORAGE CASTLE
US4590383A (en) * 1984-10-22 1986-05-20 Westinghouse Electric Corp. Spent fuel storage cask having improved fins
EP0842870A1 (en) * 1996-10-28 1998-05-20 Forschungszentrum Karlsruhe GmbH Waste receptacle for hazardous materials with a lid closure according to the double lid principle
US20040125906A1 (en) * 2002-11-09 2004-07-01 Gnb Gesellschaft Fur Nuklear-Behalter Mbh Container for heat-generating radioactive elements
US20060219960A1 (en) * 2003-01-31 2006-10-05 Kabushiki Kaisha Kobe Seiko Sho Concrete cask and method for manufacturing thereof
US7119349B1 (en) * 2003-01-31 2006-10-10 Kabushiki Kaisha Kobe Seiko Sho Concrete cask and method for manufacturing thereof
EP1622169A1 (en) * 2004-07-31 2006-02-01 GNS Gesellschaft für Nuklear-Service mbH Transport container for radioactive elements
US20060291609A1 (en) * 2005-06-23 2006-12-28 Nac International, Inc. Apparatuses and methods for mechanical shielding and cooling
US7342989B2 (en) * 2005-06-23 2008-03-11 Nac International, Inc. Apparatuses and methods for mechanical shielding and cooling
US20080137794A1 (en) * 2005-12-01 2008-06-12 Nac International, Inc. Systems and methods for loading and transferring spent nuclear fuel
US20110091003A1 (en) * 2006-01-25 2011-04-21 Commissariat A L'energie Atomique Method and device for sealing a canister loaded with irradiated nuclear fuel in a cooling pond
US8416910B2 (en) * 2006-01-25 2013-04-09 Commissariat A L'energie Atomique Method and device for sealing a canister loaded with irradiated nuclear fuel in a cooling pond
US10032533B2 (en) 2013-10-02 2018-07-24 Nac International Inc. Systems and methods for transferring spent nuclear fuel from wet storage to dry storage
US11728058B2 (en) 2013-10-02 2023-08-15 Nac International Inc. Systems and methods for transferring spent nuclear fuel from wet storage to dry storage
US9793021B2 (en) 2014-01-22 2017-10-17 Nac International Inc. Transfer cask system having passive cooling
US10770194B2 (en) * 2016-08-10 2020-09-08 Jonathan Bright Nuclear fuel storage cask
US11557405B2 (en) 2016-08-10 2023-01-17 Jonathan Bright Nuclear fuel storage cask
US10923241B2 (en) * 2016-09-30 2021-02-16 Hitachi Zosen Corporation Concrete cask

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