5. A grid structure for a nuclear reactor fuel assembly comprising a plurality of connecting members forming at least one longitudinally extending opening peripheral and inner fuel element openings through each of which openings at least one nuclear fuel element extends, said connecting members forming wall means surrounding said each peripheral and inner fuel element opening, a pair of rigid projections .Badd.longitudinally spaced from one another .Baddend.extending from a portion of said wall means into said each peripheral and inner opening for rigidly engaging said each fuel element, respectively, yet permit individual longitudinal slippage thereof, and resilient means .Badd.formed integrally on and from said wall means and .Baddend.positioned in said each peripheral and inner opening in opposed relationship with said projections and located to engage said fuel element to bias the latter into engagement with said rigid projections, respectively.
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22. A fuel arrangement for a nuclear reactor comprising a plurality of elongated fuel elements disposed in a generally parallel array, a plurality of longitudinally spaced grid members extending laterally across said fuel arrangement for positioning laterally in spaced relationship all of said fuel elements in said array that are permitted to individually expand longitudinally and slip relative to said grid members, said expanding fuel elements each of said grid members comprising a plurality of connecting members forming a plurality of fuel element openings, each of said expanding fuel elements extending through an opening in each grid member, and forming a segment of a flow channel between said fuel elements, substantially rigid means rigidly engaging one side of each of said expanding fuel elements respectively to laterally position each expanding fuel element yet permit longitudinal slippage thereof, resilient means disposed on another side of each expanding fuel element generally opposite to said one side and engaging respectively each expanding fuel element to bias the latter into engagement with said rigid means, one of said rigid means and said resilient means extending from said connecting members into said opening, and the other of said rigid means and said resilient means being located in said flow channel.
1. A grid structure for a nuclear reactor fuel assembly comprising a plurality of connecting members forming respective openings peripheral and inner fuel element openings through which each of which openings an elongated elements are fuel elements is adapted to extend, at least two rigid spaced projections extending into each of at least some of said grid peripheral and inner fuel element openings from at least one of said members, and at least one resilient means extending into each of said some peripheral and inner openings from at least another of said members and disposed generally opposite to said two rigid projections with its innermost protrusion being positioned in alignment with the region intermediate said spaced projections. .Badd.
26. The fuel arrangement of 14 wherein are .Badd.A fuel arrangement for a nuclear reactor comprising a plurality of elongated fuel elements disposed in a generally parallel array, a plurality of longitudinally spaced grid members extending laterally across said fuel arrangement, said array including fuel elements that are permitted to individually expand and contract longitudinally relative to said grid members, said grid members positioning laterally in spaced relationship all of said fuel elements in said array that are permitted to individually expand and contract longitudinally relative to said grid members, each of said grid members having respective openings therein, all of said longitudinally expandable fuel elements in said array extending through respective openings in each grid member, each of said grid members having both resilient means and substantially rigid means extending into each of said last mentioned openings for supporting all of said longitudinally expandable fuel elements against lateral displacement, and said resilient means being disposed generally opposite to said rigid means, and .Baddend.said resilient means formed integrally upon .Badd.and from .Baddend.said grid members.
2. The combination of
3. The combination of
4. A grid structure for a nuclear reactor fuel assembly comprising a plurality of connecting members forming at least one opening peripheral and inner fuel element openings through each of which, respectively, at least one elongated fuel element extends and forming forms a segment of a flow channel therebetween between said fuel elements, rigid means engaging one side of all of said elongated element elements, respectively, to laterally position said each elongated element yet permit longitudinal slippage thereof, resilient means disposed on another side of said each elongated element generally opposite to said one side and engaging said respectively each elongated element to bias the latter into engagement with said rigid means, one of said rigid means and said resilient means extending from said connecting members into said openening, peripheral and inner openings and the other of said rigid means and said resilient means being located in said flow channel. 5. A grid structure for a nuclear reactor fuel assembly comprising a plurality of connecting members forming at least one longitudinally extending opening peripheral and inner fuel element openings through each of which openings at least one nuclear fuel element extends, said connecting members forming wall means surrounding said each peripheral and inner fuel element opening, a pair of rigid projections .Badd.longitudinally spaced from one another .Baddend.extending from a portion of said wall means into said each peripheral and inner opening for rigidly engaging said each fuel element, respectively, yet permit individual longitudinal slippage thereof, and resilient means .Badd.formed integrally on and from said wall means and .Baddend.positioned in said each peripheral and inner opening in opposed relationship with said projections and located to engage said fuel element to bias the latter into engagement with said rigid projections, respectively. 6. The combination of
7. The combination of
8. The combination of
16. The combination of
20. The fuel arrangement of
21. The fuel arrangement of
23. The fuel arrangement of
24. The fuel arrangement of
25. The fuel arrangement of
27. The fuel arrangement of
28. The fuel arrangement of
29. A fuel arrangement for a nuclear reactor comprising a plurality of fuel elements disposed in a generally parallel array, means for supporting said fuel elements for limited longitudinal movement to permit expansion and contraction of each movable fuel element relative to said supporting means and independently of expansion and contraction of the other longitudinally movable fuel elements, a plurality of grid members spaced apart longitudinally of said array and each extending laterally across said array for positioning laterally in spaced relationship all of said longitudinally movable fuel elements, rigid spacer means extending longitudinally of said array between said grid members and rigidly secured to all of said grid members to space said grid members longitudinally with respect to the fuel elements, each of said grid members comprising peripheral straps and two sets of intersecting and rigidly interconnected inner straps with said inner straps of one set extending transversely of said inner straps of the other set, said inner and peripheral straps cooperating to form a plurality of openings, respective openings in said grids being aligned longitudinally of said array to form groups of aligned fuel element openings respectively accommodating the longitudinally movable fuel elements passing therethrough, there being a group of longitudinally aligned fuel element openings for each longitudinally movable fuel element, each said inner strap including a plurality of pairs of rigid means formed integrally thereon, the rigid means of each pair being spaced from each other longitudinally of the array and the different pairs being spaced apart along each strap in a direction transversely of the array, each pair of said rigid means engaging one side of one of said longitudinally movable fuel elements to laterally position each such fuel element yet permit longitudinal slippage thereof, a plurality of spaced apart resilient springs formed integrally with each inner strap, each such resilient spring being formed longitudinally intermediate one pair of said rigid means and extending outwardly from said inner strap in a direction away from the latter pair of rigid means, the resilient springs being spaced along each inner strap in a direction transversely of the array and by a distance approximating the spacing between the pairs of rigid means formed along that inner strap, said resilient springs engaging another side of said longitudinally movable fuel elements generally opposite to said one side to bias each of said longitudinally movable fuel elements into engagement with one pair of said rigid means, there being at least one pair of rigid means and one spring extending into each fuel element opening for the longitudinally movable fuel elements. 30. The fuel arrangement of
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The present invention relates to nuclear reactors and more particularly to means for supporting elements bearing fissionable material or fuel in a nuclear reactor core, but the invention can also be used to support elements in any fluid media.
One general structural form commonly used for providing a nuclear fuel inventory in nuclear reactors is that in which numerous elongated elements or rods containing fissile material are arranged, within a prescribed volume, in a parallel array in an upstanding direction between upper and lower reactor core support plates. To provide integrity in the support relations, the fuel rods are divided into groups and the rods in each group are formed as a fuel assembly prior to placement between the reactor core support plates. A fluid, having coolant and, if desired, neutron moderating properties, flows along and among the fuel rods as a vehicle for energy transfer.
Generally, means are normally provided for laterally supporting the fuel elements for reasons including that of resisting lateral displacement so as to prevent localized neutron flux peaking with resulting "hot spots" or regions of extreme temperature rise in the fuel elements. Therefore, if the "hot spots" can be eliminated, the reactor can be operated closer to its design power limit.
In the past a spring finger type grid design has been utilized to support laterally the fuel rods in a fuel assembly. This design concept provides for individual support of each fuel rod at axially spaced intervals by spring fingers, which position the fuel rods radially within the fuel assembly while permitting thermal expansion with a minimum of constraint. Although the spring finger grid design has proven to be an effective and economical means of providing fuel rod support in the past fuel assembly designs, the problems associated with this design which pose design restrictions are fretting wear, the number of grids required to provide adequate fuel rod support, and the care required during assembly and shipping of the fuel assemblies to prevent damage to the grid spring fingers.
A significant fact contributing to the aforementioned problems is the relatively small resistance to fuel rod lateral motion inherent in current grid designs which, in principle, behave as an unstable spring and mass system because the fuel rods are supported laterally by spring fingers alone. Any forces tending to cause motion of the fuel rod are not resisted (neglecting friction) until deflection of the spring fingers is such as to build up a force to stop the motion. Therefore, before any large resisting force is produced, motion has already commenced. This motion even though it may be only microscopic in magnitude may cause serious fretting under the loads and bearing stresses involved at reactor operating conditions for extended periods of time. Also, the number of grids required to provide adequate fuel rod support has an adverse effect on hydraulic and nuclear core design parameters. Another problem encountered is the extreme care and precautions against shock and accelerations during handling and shipping which are required to prevent damage to the grid spring fingers.
Accordingly, it is the general object of this invention to provide a novel means for supporting fuel elements in a fuel assembly.
Another object of this invention is to provide means for laterally supporting the fuel elements in a fuel assembly while enabling the fuel elements to respond to applied thermal or other forces with axial movement relative to the lateral supporting means.
Still another object of this invention is to provide a grid member which creates a greater resistance to fuel rod motion.
A further object of this invention is to provide an improved grid design which permits a greater unsupported length of fuel rods resulting in fewer grids and material in the fuel assembly.
Another object of this invention is to provide a grid member with greater structural integrity and greater resistance against damage from shock and acceleration forces encountered in normal handling and shipping.
Yet another object of this invention is to provide a grid member having a more stable and rugged spring finger and backup tab design, so that each fuel rod passing through the grid member is forced to assume a location in the center of the grid cell and is not permitted to assume an off-center position obtained by deflecting one spring finger more than another.
Briefly, the present invention accomplishes the above cited objects by providing a more stable spring and mass system as well as a built-in beam effect resulting in a resisting moment. The aforementioned result is accomplished by having two relatively rigid projections engaging the fuel element on one side and a spring means engaging the fuel element directly opposite to the rigid projections. Another set of identical lateral supports are provided for the elongated fuel element at the same longitudinal locations of the fuel element, but rotated approximately 90°. Therefore, a six point lateral support is provided for the fuel element.
More specifically, a nuclear fuel arrangement or assembly comprises a plurality of elongated parallel fuel elements which are supported relative to each other through the use of supporting means including elongated frame means. At least one grid member extends laterally across the frame means and has respective openings through which the fuel elements extend. The openings in the grid members are formed by a plurality of straps, which are interwoven to provide a structural network, similar to an "egg crate." The grid straps, in turn, are provided with rigid and resilient means projecting into each opening for supporting the fuel elements against lateral displacement and, to a given extent, frictionally against longitudinal movement. The rigid means comprises two longitudinally spaced rigid projections which engage the fuel element on one side. The resilient means comprises a spring which engages the fuel element directly opposite to the rigid projections at a longitudinal point preferably midway between the rigid projections. Another identical set of lateral supports are formed in the other two straps which form the opening so as to support the fuel element at the same longitudinal location, but at a lateral location approximately 90° apart from the first set of lateral supports. Thus, a six point lateral support is provided for each fuel element at each opening in the grid member.
Further objects, features and advantages of the invention will become apparent as the following description proceeds wherein features of novelty, which characterize the invention, will be pointed out with particularity.
For a better understanding of the invention, reference may be had to the accompanying drawings, in which:
FIG. 1 is a partially sectioned elevational view of a fuel assembly formed in accordance with the principles of this invention and is taken along reference line I--I of FIG. 2;
FIG. 2 is an enlarged cross sectional view of the fuel assembly of FIG. 1 and is taken along reference line II--II of FIG. 1 to show the support relationship between a grid member and the various fuel elements;
FIG. 3 is a longitudinally sectioned view of a fuel assembly and is taken along reference line III--III of FIG. 2 to show the rigid and resilient lateral supports in one of the grid straps;
FIG. 4 is a longitudinally sectioned view of a portion of a grid strap and is taken along reference line IV--IV of FIG. 3 to show the support relationship between a grid strap and the various fuel elements;
FIG. 5 is an isometric view of a plurality of grid straps with one strap being removed from the grid structure so as to show how the straps may be interlaced into a grid-like structure of "egg crate";
FIG. 6 is an enlarged longitudinally sectioned view of a grid strap of FIG. 5 and is taken along the reference line VI--VI of FIG. 5 to show another species of a rigid lateral support portion of the rigid and resilient combination used to support a fuel element;
FIG. 7 is a cross sectional view of a fuel assembly taken just above the grid structure so as to show another arrangement of the rigid and resilient lateral supports wherein resilient lateral supports are located around the periphery of the grid structure;
FIG. 8A is a longitudinally sectioned view of a portion of the grid structure of FIG. 7 and is taken along reference line VIII--VIII to show the combination of rigid lateral supporting means at certain locations in the grid structure so as to make it possible to have only resilient lateral supporting means around the periphery of the grid structure;
FIG. 8B is another embodiment of FIG. 8A, which serves the same purpose and can be used in lieu of the arrangement shown in FIG. 8A;
FIG. 9 is an elevational view of a portion of a grid structure showing an arrangement where only laterally resilient means are used to support a fuel element;
FIG. 10 is an equilibrium diagram with no externally applied forces acting on a fuel element in the grid arrangement of FIG. 9;
FIG. 11 is an equilibrium diagram with externally applied forces; tending to cause motion on a fuel element in the grid arrangement of FIG. 9;
FIG. 12 is an equilibrium diagram with no externally applied forces acting on a fuel element in the grid arrangement of FIG. 6;
FIG. 13 is an equilibrium diagram with externally applied forces acting on a fuel element in the grid arrangement of FIG. 6; and
FIG. 14 is a view in elevation of a portion of a grid structure of this invention showing a different fuel element arrangement therein.
Referring now to FIG. 1 there is shown a fuel assembly 20 comprising a plurality of elongated parallel fuel elements 22, which suitably contain a given quantity of fissionable material, and supporting means for the fuel elements 22 including elongated frame means 24 in which the fuel elements 22 are located. In this instance, the frame means or member 24 includes a plurality of arms 26, an upper end plate 28, an enclosure or can 30, and a lower end plate 32. The arms 26 have a recess 34 therein for engagement with a remote handling tool (not shown). The upper end plate 28 is secured to the bottom of the arms 26 and has flow openings 36 and fuel element openings 38. The enclosure 30, in turn, is secured to the upper end plate 28 and the lower end plate 32. The fuel elements 22 merely rest on the lower end plate 32; and, therefore, the fuel elements 22, which extend through the fuel element openings 38, can be removed individually with the fuel assembly 20 remaining in place in the reactor core (not shown). Flow openings 40 are provided in the can 30 so as to permit cross flow of the employed coolant, and the form of the coolant openings 40 is such as to maximize both this flow and structural stiffness. The lower end plate 32 also has flow openings (not shown) is a direction axially parallel to the fuel elements so as to permit coolant flow through the fuel assembly 20.
The material selected for use in forming the frame member 24 should provide maximum structural strength consistent with low neutron absorption cross section. For example, stainless steel is suitable for this purpose.
A grid member or structure 42 is secured to and extended laterally across the can 30 for the purpose of providing lateral support for the fuel elements of rods 22. A plurality of grids 42 can be secured to the can 30 at various spacings along the length of the can 30 so as to provide the amount of lateral support desired.
As viewed in FIGS. 2, 3 and 4, the grid 42 is comprised of a plurality of inner straps 44 which are interwoven in a grid-like manner. Generally, this configuration is similar to that described in copending application Ser. No. 326,070, entitled "Fuel Arrangement for a Nuclear Reactor," filed Nov. 26, 1963, now abandoned by Erling Frisch, and also assigned to the present assignee, which is a continuation of copending application Ser. No. 19,851, entitled "Fuel Arrangement for a Nuclear Reactor," now abandoned, filed Apr. 4, 1960, by Erling Frisch and also assigned to the present assignee. Therefore, the specific description of the grid 42 will be limited here to the subject matter which pertains to the present invention. Thus, it is to be noted that the inner straps 44 are interfitted through the use of opposing latching means or slots (as indicated by the reference character 46 in FIG. 5) which allow the straps 44 to be interlatched at their various intersections.
In the formation of the grid 42, the latching means are employed with all of the inner straps 44 as well as the boundary straps 45. When the straps 44 and 45 are preassembled as described, the entire assembly is then permanently secured together, for example through the use of a furnace brazing operation or by welding. The grids 42 can be welded or otherwise secured to the can 30 so as to be supported suitably for performance of the lateral fuel rod supporting function. In turn, the grid or grids 42 also contribute to rigidizing the can 30.
The grid 42 is provided with respective openings 50 for receipt of the fuel rods 22. In the example of FIG. 2, the grid 42 comprises a plurality of peripheral fuel element openings and one inner fuel element opening disposed inwardly of the peripheral fuel element openings. However, as evident from the Frisch patent application heretofore referred to, which has matured into Patent 3,379,618, more than one inner fuel element opening may be provided in the grid members 42. Each inner strap 44 is provided with resilient means, such as spring fingers or strips 52, which are deflected from the strap 44 into an adjacent opening 50 for lateral support of the fuel rods 22. Each inner strap 44 is also provided with rigid means, such as projections or dimples 54, which are located above and below each spring finger 52 and are deflected from the strap plane in a direction opposite to their respective spring fingers 52 so as to project into adjacent openings 50 for rigid lateral support of the fuel rods 22. FIG. 3 clearly shows a spring finger 52 with a dimple 54 both above and below the spring finger 52. FIG. 4, in turn, clearly shows that the spring finger 52 projects from the strap plane in a direction directly opposite to the dimples 54.
Referring to FIG. 2, the dimples 54 are shown as projecting into each opening 50 from the two adjacent inner straps 44. Spring fingers 52 can also be seen projecting into the same opening from the other two adjacent straps 44 which form the enclosure for the aforementioned opening. Therefore, each spring finger 52 engages the fuel rod 22 at a location opposite from a pair of dimples 54. Returning to FIG. 3 four guide dimples 56 and 58 are shown therein. The guide dimples 56 are aligned horizontally and project from the strap plane in one direction, while the guide dimples 58 are also aligned in a horizontal plane but project from the strap plane in the opposite direction from the dimples 56. The guide dimples 56 and 58 are tangent to the width of the slot 46 and are located vertically opposite to the slot 46. The guide dimples 56 and 58 serve to guide the straps 44 and 45 when the aforementioned straps are inserted into each other.
FIG. 4 shows how the fuel element 22 is laterally supported in one plane. Dimples 54b substantially rigidly support fuel rod 22b at points 60 and 62, while spring finger 52b resiliently supports the fuel rod 22b at point 64. Thus, the fuel rod 22b is supported at three points in one plane. An identical three-point lateral support is also provided in a plane perpendicular to the plane shown in FIG. 4. FIG. 4 also shows that the spring finger 52b engages one fuel rod 22b on one side of the strap 44a while the dimples 54a on the same strap 44a engage another fuel element 22a on the other side of the inner strap 44a. Also shown in FIG. 4 is the fact that the point 64 where spring finger 52b engages the fuel rod 22b is located approximately midway between the two points 60 and 62 where the two dimples 54b engage the fuel rod 22b.
Returning now to FIG. 2, only one type of lateral supporting means is required at the boundary straps 45, because openings 50 are only located on one side of the boundary straps 45. Therefore, only a pair of dimples 54 or a spring finger 52 project into a single opening 50. Therefore, the arrangement is such that a spring finger 52 on boundary straps 45 is located opposite to a pair of dimples 54 on the inner straps 44, or a pair of dimples 54 on boundary straps 45 are located opposite to a single spring finger 52 on inner straps 44.
All of the above features described in connection with the grid 42 are more readily discernible in the isometric view shown in FIG. 5. However, in FIGS. 5 and 6, another species of a substantially rigid lateral supporting means is shown. In this instance, the rigid lateral supporting means is a slotted projection 66 which is formed from a strap 44' and also 45'. Also shown in FIGS. 5 and 6 are several curves 68 and 70 formed in the spring finger 52. The aforementioned curves have been formed in the spring finger 52 so as to cause the spring finger 52 to flex at its ends and also to obtain the desired spring properties.
Referring now to FIG. 7, there is shown a grid structure which contains only spring fingers 52 in the boundary straps 45". The grid 42", in this instance, is secured to four corner rods or spacers 72. The rods 72, in turn, are secured to upper and lower end plates 28 and 32, respectively, shown in FIG. 1. In this instance, the rods 72 replace the can 30 previously described in connection with FIG. 1. In this type of a canless fuel assembly, it is advantageous to have only spring fingers 52 around the periphery, because if a boundary strap 45" is bent during handling, there will still be resilience available from the spring finger 52. On the other hand, if a rigid lateral supporting means, such as slotted projections 66 or dimples 54, were located in the boundary straps 45", inward bending of boundary straps 45" would cause the laterally rigid supporting means to push the fuel rods 22 out of place.
In the configuration shown in FIG. 7, a double set of dimples must be used at a single vertical location within certain adjacent grid openings 50. In FIG. 8A there is shown that dimples 54a protrude in one direction from the grid strap 44" so as to engage fuel element 22a, and another pair of dimples 54b protrude in the opposite direction from the plane of the grid strap 44" so as to engage fuel element 22b. FIG. 8B shows a different arrangement from FIG. 8A in that the two adjacent dimples 54d protrude in one direction, whereas the two outer dimples 54c protrude in the opposite direction.
In FIG. 14, the grid arrangement is formed with resilient means 52 and rigid means 54a formed only in some of the grid openings with the fuel elements 22a extending through only predetermined ones of the openings.
FIG. 9 shows a portion of a grid arrangement as described in the aforementioned copending application. In this configuration the fuel rod 22 is laterally supported by four cantilever spring tabs located 90° apart from one another in a horizontal plane. FIG. 10 represents an equilibrium diagram with the forces shown in a single plane, wherein symbol 76 represents the spring tab 74 acting on fuel element 22. The spring tab 74 also has a spring constant K. Therefore, FIG. 10 shows the static forces applied to fuel element 22.
FIG. 11 shows an equilibrium diagram resulting from a displacing force with motion of the fuel element 22 impending. FIGS. 9 to 11 represent an unstable spring and mass system and no resisting moment.
FIGS. 6, 12 and 13, on the other hand, are the counterparts of FIGS. 9, 10 and 11, respectively; however, FIGS.6, 12 and 13 represent the novel arrangement of this invention which utilizes a stable spring and mass system with a built-in beam effect.
A comparison will now be made between the novel arrangement shown in FIG. 6 in contrast to a prior arrangement as shown in FIG. 9. In FIGS. 10 to 13, the meaning of the symbols are as follows:
P=Preload on the fuel element 22 by the spring tab 74 or the spring finger 52
K=Spring constant
X=Amount of fuel element motion caused by a displacing force
Mr =Resisting moment to motion X
Md =Displacing moment
Fr =Resisting force to motion X
Fd =Displacing force
D=Distance between the projections 66
Returning now to the old arrangements shown in FIGS. 9 to 11 and with the application of external forces producing lateral fuel element motion:
F4 =(P+KX)-(P-KX=2KX
(see FIG. 11)
Mr =Fr (0) as no moment exists between the opposing forces P (see FIG. 10)
Mr =0
Md is greater than 0, because of the application of external forces
Therefore, the old arrangement represents an unstable spring and mass system since motion must commence before a resisting force Fr (neglecting friction) can be produced to react to the displacing force Fd. In addition, there is no resisting moment Mr produced within a single grid structure 42 to counteract any displacing moment Md.
Returning now to the novel arrangement shown in FIGS. 6, 12 and 13 and with the application of external forces producing lateral fuel element motion:
Fr =P+KX
(see FIG. 13) ##EQU1## as a moment arm exists between the point of rotation (see FIG. 13) ##EQU2##
The improvement in the new arrangement of FIG. 6 is readily ascertainable when the magnitude of the forces resisting motion are considered. Specifically, the force resisting fuel element displacement in the old arrangement of FIG. 9 is 2KX as compared with P+KX in the new arrangement of FIG. 6. Furthermore, the resisting force in the old arrangement of FIG. 9 requires X motion (neglecting friction) before reaching equilibrium and offers no resisting moment. This is due to the fact that one cantilever spring tab was working against the other thereby providing a resisting force which became dependent upon the motion of the spring tabs 74. This vibratory motion, even though microscopic, may result in wear and fretting of the fuel element 22.
The new arrangement of FIG. 6, however, produces a resisting force equal to the preload P on the spring finger 52; and the new arrangement also produces an appreciable resisting moment, which first must be overcome before fuel element motion can occur. Therefore, this arrangement provides the capability of establishing the spring preload forces and the resulting resisting moment large enough in magnitude, in comparison with the mechanically and hydraulically induced displacing forces experienced in the operation of a reactor core, such that there will be no motion of the fuel elements 22 at the grids 42. Therefore, the new arrangement of FIG. 6 provides a more rigid support for the fuel elements 22 in the fuel assembly 20.
While there have been shown and described what are at present considered to be the preferred embodiments of the invention, modifications thereto will readily occur to those skilled in the art. For example, the cantilever spring tabs shown in FIG. 9 can be used to replace the spring fingers in the preferred embodiment. In fact, the only thing that is required is a resilient lateral supporting means of some type. Also a solid piece of material can be secured to the strap to provide a laterally rigid supporting means in lieu of the dimples or slotted projections. Another means for making the fuel assembly more rigid is to rotate the grid member laterally 90° to 180° from an adjacent grid member. The grid structure can also be made of a material such as Inconel or stainless steel.
It is not desired, therefore, that the invention be limited to the specific arrangements shown and described. However, it is intended to cover in the appended claims all such modifications as fall within the true spirit and scope of the invention.
Andrews, Harry N., Keller, Herbert W.
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Executed on | Assignor | Assignee | Conveyance | Frame | Reel | Doc |
Jun 25 1975 | The United States of America as represented by the United States | (assignment on the face of the patent) | / |
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