CONTAINER AND SYSTEM FOR HANDLING DAMAGED NUCLEAR FUEL, AND METHOD OF MAKING THE SAME
A container and system for handling damaged nuclear fuel, and a method of making the same. In one embodiment, the invention is a damaged fuel container having a specially designed top cap that can be detachably coupled to the elongated tubular wall by simply translating the top cap into proper position within the elongated tubular wall, wherein biased locking elements automatically lock the top cap to the elongated tubular wall. In another embodiment, the vent screens of the damaged fuel container are integrally formed rather than being separate components. In still other embodiments, the lower vent screens are arranged on an upstanding portion of the damaged fuel container. In an even further embodiment, the elongated tubular wall is formed by an extrusion process.
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This application is a continuation of U.S. patent application Ser. No. 15/689,571 filed Aug. 29, 2017, which is a continuation of U.S. patent application Ser. No. 14/239,752 filed Mar. 21, 2014, which is a U.S. national stage application under 35 U.S.C. § 371 of PCT Application No. PCT/US12/51634, filed on Aug. 20, 2012, which claims the benefit of U.S. Provisional Patent Application No. 61/525,583, filed Aug. 19, 2011, the entireties of which are incorporated herein by reference.
FIELD OF THE INVENTIONThe present invention relates generally to containers and systems for handling nuclear fuel, and specifically to containers and systems for handling nuclear fuel whose physical integrity has been compromised, and methods of making the same.
BACKGROUND OF THE INVENTIONDamaged nuclear fuel is nuclear fuel that is in some way physically impaired. Such physical impairment can range from minor cracks in the cladding to substantial degradation on various levels. When nuclear fuel is damaged, its uranium pellets are no longer fully contained in the tubular cladding that confines the pellets from the external environment. Moreover, damaged nuclear fuel can be distorted from its original shape. As such, special precautions must be taken when handling damaged nuclear fuel (as compared to handling intact nuclear fuel) to ensure that radioactive particulate matter is contained. Please refer to USNRC's Interim Staff Guidance #2 for a complete definition of fuel that cannot be classified as “intact” and, thus, falls into the category of damaged nuclear fuel for purposes of this application. As used herein, damaged nuclear fuel also includes nuclear fuel debris.
Containers and systems for handling damaged nuclear fuel are known. Examples of such containers and systems are disclosed in U.S. Pat. No. 5,550,882, issued Aug. 27, 1996 to Lehnart et al., and U.S. Patent Application Publication No. 2004/0141579, published Jul. 22, 2004 to Methling et al. While the general structure of a container and system for handling damaged nuclear fuel is disclosed in each of the aforementioned references, the containers and systems disclosed therein are less than optimal for a number of reasons, including inferior venting capabilities of the damaged nuclear fuel cavity, difficulty of handling, inability to be meet tight tolerances dictated by existing fuel basket structures, lack of adequate neutron shielding, and/or manufacturing complexity or inferiority.
Thus, a need exists for an improved container and system for handling damaged nuclear fuel, and methods of making the same.
SUMMARY OF THE INVENTIONIn one embodiment, the invention can be a method of forming an elongated tubular container for receiving damaged nuclear fuel, the method comprising: a) extruding, from a material comprising a metal and a neutron absorber, an elongated tubular wall having a container cavity; b) forming, from a material comprising a metal that is metallurgically compatible with the metal of the elongated tubular wall, a bottom cap comprising a first screen having a plurality of openings; and c) autogenously welding the bottom cap to a bottom end of the elongated tubular wall, the plurality of openings of the first screen forming vent passageways to a bottom of the container cavity.
In another embodiment, the invention can be a container for receiving damaged nuclear fuel, the method comprising: an extruded tubular wall forming a container cavity about a container axis, the extruded tubular wall formed of a metal matrix composite having neutron absorbing particulate reinforcement; a bottom cap coupled to a bottom end of the extruded tubular wall; a top cap detachably coupled to a top end of the extruded tubular wall; a first screen comprising a plurality of openings that define lower vent passageways into a bottom of the container cavity; and a second screen comprising a plurality of openings that define upper vent passageways into a top of the container cavity.
In yet another embodiment, the invention can be a system for storing and/or transporting nuclear fuel comprising: a vessel comprising defining a vessel cavity and extending along a vessel axis; a fuel basket positioned within the vessel cavity, the fuel basket comprising a grid forming a plurality of elongated cells, each of the cells extending along a cell axis that is substantially parallel to the vessel axis; and at least one elongated tubular container comprising a container cavity containing damaged nuclear fuel positioned within one of the cells, the elongated tubular container comprising: an extruded tubular wall forming a container cavity about a container axis, the extruded tubular wall formed of a metal matrix composite having neutron absorbing particulate reinforcement; a bottom cap coupled to a bottom end of the extruded tubular wall; a top cap detachably coupled to a top end of the extruded tubular wall; a first screen comprising a plurality of openings that define lower vent passageways into a bottom of the container cavity; and a second screen comprising a plurality of openings that define upper vent passageways into a top of the container cavity.
In still another embodiment, the invention can be a system for storing and/or transporting nuclear fuel comprising: a vessel defining a vessel cavity and extending along a vessel axis; a fuel basket positioned within the vessel cavity, the fuel basket comprising a plurality of elongated cells; an elongated tubular container positioned within one of the cells, the elongated tubular container comprising: an elongated tubular wall forming a container cavity about a container axis, the tubular wall comprising a top portion having a plurality of locking apertures and a top edge defining a top opening into the container cavity; a bottom cap coupled to a bottom end of the elongated tubular wall; a top cap comprising a plurality of locking elements that are alterable between a retracted state and an extended state, the locking elements biased into the extended state; a first screen comprising a plurality of openings that define lower vent passageways between the vessel cavity and a bottom of the container cavity; a second screen comprising a plurality of openings that define upper vent passageways between the vessel cavity and a top of the container cavity; and the top cap and the elongated tubular wall configured so that upon the top cap being inserted through the top opening, contact between the locking element and the elongated tubular wall forces the locking elements into a retracted state, and wherein upon the locking element becoming aligned with the locking apertures, the locking elements automatically returning the extended state such that the locking member protrude into the locking apertures, thereby detachably coupling the top cap to elongated tubular wall.
In a further embodiment, the invention can be a system for storing and/or transporting nuclear fuel comprising: a vessel defining a vessel cavity and extending along a vessel axis; a fuel basket positioned within the vessel cavity, the fuel basket comprising a plurality of elongated cells; an elongated tubular container comprising a container cavity for containing damaged nuclear fuel positioned within one of the cells, the elongated tubular container comprising: a first screen comprising a plurality of openings that define lower vent passageways between the vessel cavity and a bottom of the container cavity, the plurality of openings of the first screen comprising a lowermost opening that is a first distance from a floor of the vessel cavity and an uppermost opening that is a second distance from the floor of the vessel cavity, the second distance being greater than the first distance; and a second screen comprising a plurality of openings that define upper vent passageways between the vessel cavity and a top of the container cavity.
In an even further embodiment, the invention can be a system for storing and/or transporting nuclear fuel comprising: a vessel defining a vessel cavity and extending along a vessel axis; a fuel basket positioned within the vessel cavity, the fuel basket comprising a plurality of elongated cells; an elongated tubular container comprising a container cavity for containing damaged nuclear fuel positioned within one of the cells, the elongated tubular container comprising: a first screen comprising a plurality of openings that define lower vent passageways between the vessel cavity and a bottom of the container cavity, the first screen located on an upstanding portion of the elongated tubular container that is substantially non-perpendicular to the vessel axis; and a second screen comprising a plurality of openings that define upper vent passageways between the vessel cavity and a top of the container cavity.
In a still further embodiment, the invention can be a damaged fuel container, or system incorporating the same, in which the one or more of the screens of the container are integrally formed into the body of the container.
Further areas of applicability of the present invention will become apparent from the detailed description provided hereinafter. It should be understood that the detailed description and specific examples, while indicating the preferred embodiment of the invention, are intended for purposes of illustration only and are not intended to limit the scope of the invention.
The present invention will become more fully understood from the detailed description and the accompanying drawings, wherein:
The following description of the illustrated embodiment(s) is merely exemplary in nature and is in no way intended to limit the invention, its application, or uses.
The description of illustrative embodiments according to principles of the present invention is intended to be read in connection with the accompanying drawings, which are to be considered part of the entire written description. In the description of embodiments of the invention disclosed herein, any reference to direction or orientation is merely intended for convenience of description and is not intended in any way to limit the scope of the present invention. Relative terms such as “lower,” “upper,” “horizontal,” “vertical,” “above,” “below,” “up,” “down,” “top” and “bottom” as well as derivatives thereof (e.g., “horizontally,” “downwardly,” “upwardly,” etc.) should be construed to refer to the orientation as then described or as shown in the drawing under discussion. These relative terms are for convenience of description only and do not require that the apparatus be constructed or operated in a particular orientation unless explicitly indicated as such. Terms such as “attached,” “affixed,” “connected,” “coupled,” “interconnected,” and similar refer to a relationship wherein structures are secured or attached to one another either directly or indirectly through intervening structures, as well as both movable or rigid attachments or relationships, unless expressly described otherwise. Moreover, the features and benefits of the invention are illustrated by reference to the exemplified embodiments. Accordingly, the invention expressly should not be limited to such exemplary embodiments illustrating some possible non-limiting combination of features that may exist alone or in other combinations of features; the scope of the invention being defined by the claims appended hereto.
Referring first to
The DFC 100 is an elongated tubular container that extends along a container axis C-C. As will become more apparent from the description below, the DFC 100 is specifically designed so as to not form a fluid-tight container cavity 101 therein. This allows the container cavity 101 of the DFC 100, and its damaged nuclear fuel payload, to be adequately dried for dry storage using standard dry storage dehydration procedures. Suitable dry storage dehydration operations and equipment that can be used to dry the DFC 100 (and the system 1000) are disclosed in, for example: U.S. Patent Application Publication No. 2006/0288607, published Dec. 28, 2006 to Singh; U.S. Patent Application Publication No. 2009/0158614, published Jun. 2, 2009 to Singh et al.; and U.S. Patent Application Publication No. 2010/0212182, published Aug. 22, 2010 to Singh. While a fluid-tight boundary is not formed by the DFC 100, the DFC 100 (when fully assembled as shown in
The DFC 100 generally comprises an elongated tubular wall 10, a bottom cap 20 and a top cap 30. In one embodiment, the elongated tubular wall 10 is formed of a material comprising a metal and a neutron absorber. As used herein the term “metal” includes metals and metal alloys. In certain embodiments, suitable metals may include without limitation aluminum, steel, lead, and titanium while suitable neutron absorbers may include without limitation boron, boron carbide and carborundem. As used herein, the term “aluminum” includes aluminum alloys. In one specific embodiment, the metal is an aluminum and the neutron absorber material is boron or boron carbide. In other embodiments, the elongated tubular wall 10 is formed entirely of a metal matrix composite having neutron absorbing particulate reinforcement. Suitable metal matrix composites having neutron absorbing particulate reinforcement include, without limitation, a boron carbide aluminum matrix composite material, a boron aluminum matrix composite material, a boron carbide steel matrix composite material, a carborundum aluminum matrix composite material, a carborundum titanium matrix composite material and a carborundum steel matrix composite material. Suitable aluminum boron carbide metal matrix composites are sold under the name Metamic® and Boralyn®. The use of an aluminum-based metal matrix composite ensures that the DFC 100 will have good heat rejection capabilities.
The boron carbide aluminum matrix composite material of which the elongated tubular wall 10 is constructed, in one embodiment, comprises a sufficient amount of boron carbide so that the elongated tubular wall 10 can effectively absorb neutron radiation emitted from the damage nuclear fuel loaded within the container cavity 101, thereby shielding adjacent nuclear fuel (damaged or intact) in the fuel basket 400 from one another (
The elongated tubular wall 10 extends along the container axis C-C from a top end 11 to a bottom end 12. The top end 11 terminates in a top edge 13 while the bottom end 12 terminates in a bottom edge 14. The elongated tubular wall 10 also comprises an outer surface 15 and an inner surface 16 that forms a container cavity 101. The top edge 13 defines a top opening 17 that leads into the container cavity 101.
The elongated tubular wall 10 comprises a top portion 18 and a bottom portion 19. In the exemplified embodiment, the bottom portion 19 extends from the bottom edge 14 to a transition shoulder 21 while the top portion 18 extends from the transition shoulder 21 to the top edge 13. The top portion 19, in the exemplified embodiment, is an upper section of the elongated tubular wall 10 that flares slightly outward moving from the transition shoulder 21 to the top edge 13. Thought of another way, the top portion 19 of the elongated tubular wall 10 has a transverse cross-section that gradually increases in size moving from the transition shoulder 21 to the top edge 13. The bottom portion 18, in the exemplified embodiment, has a substantially constant transverse cross-section along its length, namely from the bottom edge 14 to the transition shoulder 21. In other embodiments, the top portion 19 can also have a transverse cross-section that is substantially constant along its length from the transition shoulder 21 to the top edge 13. In such an embodiment, the transverse cross-section of the top portion can be larger than the transverse cross-section of the bottom portion 18. In still other embodiments, the elongated tubular wall 10 may have a substantially constant transverse cross-section along its entire length from the bottom edge 14 to the top edge 13. In such an embodiment, the elongated tubular wall 10 will be devoid of a transition shoulder 21 and the top and bottom portions 18, 19 would have no physical distinction.
In the exemplified embodiment, the elongated tubular wall 10 has a substantially constant thickness along its entire length. In one embodiment, the elongated tubular wall 10 has a wall thickness between 1 mm to 3 mm, with about 2 mm being preferred. Of course, the invention is not so limited and the elongated tubular wall 10 can have wall thickness that is variable and of different empirical values and ranges.
The inner surface 16 of the elongated tubular wall 10 defines the container cavity 101. In the exemplified embodiment, the portion of the container cavity 101 defined by the bottom portion 18 has a transverse cross-section that is substantially constant in size while the portion of the container cavity 101 defined by the top portion 19 has a transverse cross-section that increases in size moving from the transition shoulder 21 to the top edge 13.
In the exemplified embodiment, the elongated tubular wall 10 has a transverse cross-section that is substantially rectangular in shape along its entire length from the bottom edge 14 to the top edge 13. Similarly, the container cavity 101 also has a transverse cross-section that is substantially rectangular in shape along its entire length. Of course, the transverse cross-sections can be other shapes in other embodiments, and can even be dissimilar shapes between the top and bottom portions 18, 19.
The bottom cap 20 is fixedly coupled to the bottom end 12 of the elongated tubular wall 10 while the top cap 30 is detachably coupled to the top end 11 of the elongated tubular wall 10. More specifically, the bottom cap 20 is coupled to the bottom edge 14 of the elongated tubular wall 10. As will be described in greater detail below, in the exemplified embodiment, the bottom cap 20 is fixedly coupled to the bottom end 12 of the elongated tubular wall 10 by an autogenous welding technique, such as by friction stir welding. In other embodiments, the bottom cap 20 is fixedly coupled to the bottom end 12 of the elongated tubular wall 10 using other connection techniques.
The bottom cap 20, in certain embodiments, is formed of a material comprising a metal that is metallurgically compatible with the metal of the elongated tubular wall 10 for welding. In one embodiment, the bottom cap is formed of aluminum. The bottom cap 20, in a preferred embodiment, is formed by a casting process.
The bottom cap 20 comprises a plurality of first screens 22. Each of the first screens 22 comprises a plurality of openings 23 that define lower vent passageways into a bottom 102 of the container cavity 101. While in the exemplified embodiment the first screens 22 are incorporated into the bottom cap 20, the first screens 22 can be incorporated into the bottom end 12 of the elongated tubular wall 10 in other embodiments. Furthermore, while the exemplified DFC 100 comprises four first screens in the exemplified embodiment, more or less first screens 22 can be included in other embodiments.
In one embodiment, the openings 23 of the first screens 22 are small enough so that radioactive particulate matter cannot pass therethrough but are provided in sufficient density (number of openings/area) to allow sufficient venting of air, gas or other fluids through the container cavity 101. In one embodiment, the openings 23 have a diameter in a range of 0.03 mm to 0.1 mm, and more preferably a diameter of about 0.04 mm. The openings 23 may be provided for each of the first screens 22, in certain embodiments, to have a density of 200 to 300 holes per square inch. The invention, however, is not limited to any specific dimensions or hole density unless specifically claimed.
In the exemplified embodiment, the first screens 22 are integrally formed into a body 24 of the bottom cap 20 by creating the openings 23 directly into the body 24 of the bottom cap 20. The openings 23 can be formed into the body 24 of the bottom cap 20 by punching, drilling or laser cutting techniques. In one embodiment, it is preferred to form the openings using a laser cutting technique. Laser cutting allows very fine openings 23 to be formed with precision and efficiency. In alternate embodiments, the openings of the first screens 22 may not be integrally formed into the bottom cap 20 (or the elongated tubular wall 10). Rather, larger through holes can be formed in the bottom cap 20 that are then covered by separate first screens 22, such as wire mesh screens.
Referring now to
The floor plate 25 comprises a top surface 28 that forms a floor of the container cavity 101. As can be seen in
The openings 23 of each of the first screens 22 comprise a lowermost opening(s) 23A and an uppermost opening(s) 23C. The lowermost opening 23A is located a first axial distance d1 above the floor 28 of the container cavity 101 while the uppermost most opening 23C is located a second distance d2 above the floor 28 of the container cavity 101. The second distance d2 is greater than the first distance d1. As discussed below, the DFC 100, in certain embodiments, is intended to be oriented so that the container axis C-C is substantially vertical when the DFC 100 is positioned within the fuel basket 400 of the vessel 500 for transport and/or storage. Thus, in the exemplified embodiment, both the lowermost and uppermost openings 23A, C are located a vertical distance above the floor 28 of the container cavity 101. As a result, the first screens 22 are unlikely to become clogged by settling particulate debris as each of d1 and d2 are vertical distances.
As mentioned above, it is beneficial to have the first screens 22 located on an upstanding portion of the DFC 100, which in the exemplified embodiment is the oblique wall 26 of the bottom cap 20. In other embodiments, the bottom cap 20 is designed so that the wall 26 is not oblique to the container axis C-C but rather substantially parallel thereto. In such and embodiment, the first screens 22 are located on this vertical annular wall of the bottom cap 20. In still another embodiment, the bottom cap 20 may simply be a floor plate without any significant upstanding portion. In such an embodiment, the first screens 22 can be located on the bottom end 12 of the elongated tubular wall 10 itself, which would be considered the upstanding portion that is substantially parallel to container axis C-C. Of course, in such embodiments, the upstanding portion of the elongated tubular wall 10 on which the first screens 22 are located can be oriented oblique to the container axis C-C.
Referring now to
The top cap 30 comprises a body 33. In one embodiment, the body 33 is formed of any of the materials described above for the elongated tubular wall 10. In another embodiment, the body 33 is formed of any of the materials described above for the bottom cap 20.
The top cap 30 has a bottom surface 34, a top surface 32 and a peripheral sidewall 35. The peripheral sidewall 35 comprises a chamfered portion 36 at a lower edge thereof to facilitate insertion into the top opening 17 of the elongated tubular wall 10. The top cap 30 has a transverse cross-sectional shape that is the same as the transverse cross-sectional shape of the container cavity 101.
A plurality of locking elements 37 protrude from the peripheral sidewall 35 of the top cap 30 and, as discussed in greater below, are alterable between a fully extended state (shown in
The top cap 30 also comprises a second screen 38. The second screen 38 comprises a plurality of openings 39 that define upper vent passageways into a top 103 of the container cavity 101. While in the exemplified embodiment the second screen 38 is incorporated into the top cap 30, the second screen 38 can be incorporated into the elongated tubular wall 10 at a position below where the top cap 30 couples to the elongated tubular wall 10 in other embodiments.
In one embodiment, the openings 39 of the top cap are small enough so that radioactive particulate matter cannot pass therethrough but are provided in sufficient hole density (number of openings/area) to allow sufficient venting of air and gases (or other fluids) through the container cavity 101. In one embodiment, the openings 39 have a diameter in a range of 0.03 mm to 0.1 mm, and more preferably a diameter of about 0.04 mm. The openings 39 may be provided for the second screen 38, in certain embodiments, to have a density of 200 to 300 holes per square inch. The invention, however, is not limited to any specific dimensions or hole density of the openings 39 unless specifically claimed.
In the exemplified embodiment, the second screen 38 is integrally formed into the body 33 of the top cap 30 by creating the openings 39 directly into the body 33 of the bottom cap 20. The openings 39 can be formed into the body 33 of the top cap 30 by punching, drilling or laser cutting techniques. In one embodiment, it is preferred to form the openings 39 using a laser cutting technique. Laser cutting allows very fine openings 39 to be formed with precision and efficiency. In alternate embodiments, the openings 39 of the second screen 38 may not be integrally formed into the top cap 30 (or the elongated tubular wall 10). Rather, larger through holes can be formed in the top cap 30 that are then covered by a separate second screen(s), such as a wire mesh screen(s).
Referring now to
Referring solely now to
As described in greater detail below, the locking elements 37 are forced from the fully extended state to the fully retracted state due to contact between the extruded tubular wall 10 and the locking elements 37 during insertion of the top cap 30 into the container cavity 101. As can be seen in
As mentioned above, the locking elements 37 are biased into a fully extended state and, thus, protrude from all four sections of the peripheral sidewall 35. As a result of the protruding locking elements 37, the top cap 37 has an effective transverse cross-section A3 when the locking elements 37 are in the fully extended state. The DFC 100 is designed, in the exemplified embodiment, so that the effective transverse cross-section A3 of the top cap 30 is the same as or smaller than the transverse cross-section A1 of the top opening 17 of the internal cavity 101. The effective transverse cross-section A3 of the top cap 30, however, is greater than the transverse cross-section A2 of the container cavity 101 at the axial position immediately above locking apertures 50.
Referring now to
As the top cap 30 continues to be inserted (i.e., lowered in the illustration), the locking elements 37 come into contact with the inner surface 16 of the top portion 19 of the elongated tubular wall 10 that defines that portion of the container cavity 101. Due to the fact that the inner surface 16 is sloped such that the transverse cross-section of the container cavity 101 continues to decrease with distance from the top edge 13, the locking elements 37 are further forced into retraction by the inner surface 16 of the elongated tubular wall 10 until a fully retracted state is achieved at the axial position immediately above locking apertures 50 (
Referring to
The exemplified embodiment is only one structural implementation in which the top cap 30 and the elongated tubular wall 10 are configured so that upon the top cap 30 being inserted through the top opening 17, contact between the locking elements 37 and the elongated tubular wall 10 forces the locking elements 37 into a retracted state. In other embodiments, the effective transverse cross-section A3 of the top cap 30 may be larger than the transverse cross-section A1 of the top opening 17 of the internal cavity 101. In such an embodiment, the lower edges of the locking elements 37 can be appropriately chamfered and/or rounded so that upon coming into contact with the top edge 13 of the elongated tubular wall 10 during lowering, contact between the lower edges of the locking elements 37 and the top edge 13 of the elongated tubular wall 10 forces the locking elements 37 to translate inward along their locking element axes L-L. In other embodiments, the top edge 13 of the elongated tubular wall 10 may be appropriately chamfered to achieve the desired translation of the locking elements 37.
Referring now to
The vessel 500 comprises a cylindrical shell 502, a lid plate 503 and a floor plate 504. The lid plate 503 and the floor plate 504 are seal welded to the cylindrical shell 502 so to form the hermetically sealed vessel cavity 501. A top surface 505 of the floor plate 504 forms a floor of the vessel cavity 501. The vessel 500 extends along a vessel axis V-V, which is arranged substantially vertical during normal operation and handling procedures.
The fuel basket 400 is positioned within the vessel cavity 502 and comprises a gridwork 401 forming a plurality of elongated cells 403A-B. In the exemplified embodiment, the gridwork 401 is formed by a plurality of intersecting plates 402 that form the cells 403A-B. In one embodiment, the plates 402 that form the gridwork 401 are formed of stainless steel. Because the elongated tubular wall 10 of the DFC 100 is made of a boron carbide aluminum matrix composite material, or a boron aluminum matrix composite material, and the gridwork 401 is made of stainless steel, there is no risk of binding from the cohesion effect of materials of identical genre.
Each of the elongated cells 403A-B extend along a cell axis B-B that is substantially parallel to the vessel axis V-V. The plurality of cells 403A-B comprises a first group of cells 403A that are configured to receive intact nuclear fuel 50 and a second group of cells 403B configured to receive DFCs 100 containing damage nuclear fuel. Each of the cells 403A of the first group comprise neutron absorbing liner panels 404 while the each of the cells 403B of the second group are free of the neutron absorbing liner panels 404. In one embodiment, the neutron absorbing liner panels 404 can be constructed of the same material that is described above for the elongated tubular wall 10.
Because the elongated tubular wall 10 of the DFC 100 incorporate neutron absorber as described above, the cells 403B of the fuel basket 400 that are to receive the DFCs 100 do not require such neutron absorber plates 404, leading to an increased cell cavity size which is large enough to enable free insertion or extraction of the DFC 100 from the fuel basket 400. In certain embodiments, the cell opening of the cells 403B is 6.24 inches, which means that there is a ¼ inch lateral gap between the DFC 100 and the grid that forms the storage cell 403B. Moreover, because the DFC 100 is extruded and the cells 403A-B of the fuel basket 400 are of honeycomb construction made of thick plate stock (¼ inch wall), there is a high level of confidence that the DFCs 100 can be inserted into the storage cells 403B without interference. In the exemplified embodiment, all of the cells 403A-B have the same pitch therebetween.
Referring now to
As mentioned above, the cell axis B-B is substantially parallel to the vessel axis V-V. Thus, when the DFC 100 is loaded within the cell 403B, the oblique wall 26 of the bottom cap 20 is oblique to both the cell axis B-B and the vessel axis V-V. As mentioned above, the top surface 505 of the floor plate 504 forms a floor of the vessel cavity 501. Thus, when the DFC 100 is loaded within the cell 403B, the lowermost opening(s) 23A of the first vent(s) 22 is a distance d3 above the floor 505 of the vessel 500 while the uppermost opening(s) 23C of the first vent(s) 22 is a distance d4 above the floor 505 of the vessel 500.
In summary, the DFC 100 of the present invention fits in the storage cell 403B with adequate clearance. The DFC 100 also provides adequate neutron absorption to meet regulatory requirements. The DFC 100 also confines the particulates but allow water and gases to escape freely. The DFC 100 also features a robust means for handling and includes a smooth external surface to mitigate the risk of hang up during insertion in or removal from the storage cell 403 B. The DFC also provides minimal resistance to the transmission of heat from the contained damaged nuclear fuel. The loaded DFC 100 can be handled by a grapple from the Fuel Handling Bridge. All lifting appurtenances are designed to meet ANSI 14.6 requirements with respect to margin of safety in load handling. Specifically, the maximum primary stress in any part of the DFC 100 will be less than its Yield Strength at 6 times the dead weight of the loaded DFC,W. and less than the Ultimate Strength at 10 times W.
The table below provides design data for one embodiment of the DFC 100.
A method of manufacturing the DFC 100 according to an embodiment of the present invention will now be described. First, the elongated tubular wall 10 is formed via an extrusion process using a metal matrix composite having neutron absorbing particulate reinforcement. A boron carbide aluminum matrix composite material is preferred. At this stage, the extruded elongated tubular wall 10 (and the container cavity 101) has a substantially constant transverse cross-section, with the elongated tubular wall 10 also having a substantially uniform wall thickness. The elongated tubular wall 10 is then taken and a portion thereof is expanded so that the container cavity 101 has an increased transverse cross-section, thereby forming the top portion 19 and the bottom portion 18 elongated tubular wall 10. Expansion of the container cavity 101 (which can also be considered expansion of the elongated tubular wall 10) can be accomplished using a swaging process using an appropriate mandrel, die and/or press. Said swaging process can be a hot work in certain embodiments. In an alternate embodiment, the difference sizes in transverse cross-section of the container cavity 101 can be accomplished by performing a drawing process to reduce the bottom portion 18 of the elongate tubular wall 10.
The locking apertures 50 are then formed into the top portion of the elongated tubular wall 10 via a punching, drilling, or laser cutting technique.
The bottom cap 20 is then formed. Specifically, the bottom cap 20 is formed by casting aluminum to form the cap body 24. The plurality of openings 23 are then integrally formed therein using a laser cutting process to form the first screens 22 on the oblique wall 26.
The bottom cap 20 is then autogenously welded to the bottom end 12 of the elongated tubular wall 10. More specifically, the bottom cap 20 is butt welded to the bottom end 12 of the elongated tubular wall 10 to produce a weld junction that is smooth with the outer surface 15 of the elongated tubular wall 10. A friction stir weld technique may be used.
The top cap 30 is then formed and coupled to the elongated tubular wall 10 as described above.
While the invention has been described with respect to specific examples including presently preferred modes of carrying out the invention, those skilled in the art will appreciate that there are numerous variations and permutations of the above described systems and techniques. It is to be understood that other embodiments may be utilized and structural and functional modifications may be made without departing from the scope of the present invention. Thus, the spirit and scope of the invention should be construed broadly as set forth in the appended claims.
Claims
1. A method of forming an elongated tubular container for receiving damaged nuclear fuel, the method comprising:
- a) extruding, from a material comprising a metal and a neutron absorber, an elongated tubular wall having a container cavity;
- b) forming, from a material comprising a metal that is metallurgically compatible with the metal of the elongated tubular wall, a bottom cap comprising a first screen having a plurality of openings; and
- c) autogenously welding the bottom cap to a bottom end of the elongated tubular wall, the plurality of openings of the first screen forming vent passageways to a bottom of the container cavity.
2. The method according to claim 1 wherein step b) further comprises:
- b-1) casting a body of the bottom cap; and
- b-2) integrally forming the plurality of openings into the body of the bottom cap to form the first screen.
3. The method according to claim 2 wherein the plurality of openings are integrally formed by laser cutting the plurality of openings into the body of the bottom cap.
4. The method according to claim 1 wherein the elongated tubular wall is formed of a metal matrix composite having neutron absorbing particulate reinforcement.
5. The method according to claim 4 wherein the metal matrix composite having neutron absorbing particulate reinforcement is a boron carbide aluminum matrix composite material.
6. The method according to claim 1 wherein the bottom cap is formed of aluminum.
7. The method according to claim 1 wherein step c) further comprises:
- c-1) butt welding the bottom cap to the bottom end of the elongated tubular wall to produce a weld junction that is smooth with an outer surface of the elongated tubular wall.
8. The method according to claim 1 wherein the container cavity of the elongated tubular wall resulting from step a) has a substantially constant transverse cross-section.
9. The method according to claim 8 further comprises:
- expanding a portion of the transverse cross-section of the container cavity along a top portion of the elongated tubular wall.
10. The method according to claim 9 wherein the expanded portion of the transverse cross-section of the container cavity tapers moving away from a top edge of the elongated tubular wall.
11. The method according to claim 1 further comprising:
- d) forming a top cap having a second screen comprising a plurality of openings; and
- e) detachably coupling the top cap to the elongated tubular wall, the plurality of openings of the first cap forming vent passageways into a top of the container cavity.
12. The method according to claim 11 wherein step e comprises:
- e-1) sliding the top cap into an open top end of the container cavity, wherein locking elements of the top cap that are normally biased into an extended state are forced into a retracted state due to contact with the elongated tubular wall during said sliding; and
- e-2) upon the locking elements of the top cap becoming aligned with locking apertures of the elongated tubular container, the locking elements automatically returning to the extended state such that the locking elements protrude into the locking apertures.
13. A system for storing and/or transporting nuclear fuel comprising:
- a vessel comprising defining a vessel cavity and extending along a vessel axis;
- a fuel basket positioned within the vessel cavity, the fuel basket comprising a grid forming a plurality of elongated cells, each of the cells extending along a cell axis that is substantially parallel to the vessel axis; and
- at least one elongated tubular container comprising a container cavity containing damaged nuclear fuel positioned within one of the cells, the elongated tubular container comprising: an extruded tubular wall forming a container cavity about a container axis, the extruded tubular wall formed of a metal matrix composite having neutron absorbing particulate reinforcement; a bottom cap coupled to a bottom end of the extruded tubular wall; a top cap detachably coupled to a top end of the extruded tubular wall; a first screen comprising a plurality of openings that define lower vent passageways into a bottom of the container cavity; and a second screen comprising a plurality of openings that define upper vent passageways into a top of the container cavity.
14. The system according to claim 13 wherein a top portion of the extruded tubular wall comprises locking apertures, and the top cap comprises locking elements that are alterable between a retracted state and an extended state, the locking elements biased into the extended state, and wherein the top cap is detachably coupled to the extruded tubular wall when the locking elements are in the extended state and protrude into the locking apertures.
15. The system according to claim 14 wherein contact between the extruded tubular wall and the locking elements forces the locking elements into the retracted state during insertion of the top cap into the container cavity until the locking elements become aligned with the locking apertures.
16. The system according to claim 14 wherein the bottom cap comprises the first screen and the top cap comprises the second screen.
17. The system according to claim 16 wherein the first screen is integrally formed into a body of the bottom cap and the second screen is integrally formed into a body of the top cap.
18. The system according to claim 13 wherein the bottom cap comprises a floor plate that forms a floor of the container cavity and an oblique wall plate extending upward from a perimeter of the floor plate, the oblique wall plate coupled to the bottom end of the extruded tubular wall, the first screen located on the oblique wall plate of the bottom cap.
19. The system according to claim 13 further comprising a floor of the container cavity, and wherein at least one of the plurality of openings of the first screen is located an axial distance above the floor of the container cavity.
20. The system according to claim 15, wherein the locking elements are spring biased laterally outward towards the extended state.
Type: Application
Filed: Jun 16, 2020
Publication Date: Oct 1, 2020
Applicant: Holtec International (Camden, NJ)
Inventor: Krishna P. Singh (Hobe Sound, FL)
Application Number: 16/902,387