Patent Number: 047524413
Section: description

DETAILED DESCRIPTION OF THE INVENTION FIG. 1 is an elevational view, partly in cross-section, of an advanced design pressurized water reactor 10 of the type with which the modular formers of the present invention are intended to be employed, and which comprises a vessel 12 of generally conventional configuration including an upper dome 12a, cylindrical sidewalls 12b, and a bottom closure 12c comprising the base of the reactor 10. Within the bottom closure 12c, there is schematically indicated so-called bottom-mounted instrumentation 14. The lower barrel assembly 16 comprises a generally cylindrical sidewall 17 affixed at its lower and upper ends to respective lower and upper core plates 18 and 19. Fuel rod assemblies 20 are positioned in generally vertically oriented, parallel axial relationship within the lower barrel assembly 16. A radiation reflection shield 21 is mounted interiorly of the cylindrical sidewalls 17, in conventional fashion. The inner barrel assembly 24 includes a cylindrical sidewall 26 within which are positioned a plurality of rod guides in closely spaced, parallel axial relationship; for simplicity of illustration, only two such rod guides are shown in FIG. 1, namely rod guide 28 housing a cluster of radiation control rods 30 (RCC) and a rod guide 32 housing a cluster of water displacement rods 33 (WDRC). Mounting means 36 and 37 are provided at the respective upper and lower ends of the rod guide 28 and, correspondingly, mounting means 38 and 39 are provided at the respective upper and lower ends of the rod guide 32, the lower end mounting means 37 and 39 mounting the respective rod guides 28 and 32 to the upper core plate 19. The upper mounting means 36 and 38 mount the respective rod guides 28 and 32 to a calandria assembly 50, and which may be of the types disclosed in the concurrently filed applications entitled TOP END SUPPORT FOR WDRC ROD GUIDES OF PRESSURIZED WATER REACTOR and FLEXIBLE ROD GUIDE SUPPORT STRUCTURE FOR INNER BARREL ASSEMBLY OF PRESSURIZED WATER REACTOR, each having a common co-inventor herewith and assigned to the common assignee hereof. Three banks of modular formers 40, 42 and 44, in accordance with the present invention, spaced at successively higher elevations within the inner barrel assembly 24 and affixed to the interior surface of the cylindrical sidewall 26 thereof, are provided to establish the proper pressure drop of the core outlet flow from the lower barrel assembly 16, as it passes upwardly through the inner barrel assembly 24, so as to approach an axial flow condition in the region of the rod guides 28 and 30 in a manner and for reasons to be more fully described hereinafter. The calandria assembly 50 includes a lower calandria plate 52, an upper calandria plate 54, and a plurality of parallel axial calandria tubes 56 which are positioned in alignment with corresponding apertures in the lower and upper calandria plates 52 and 54 and to which the calandria tubes 56 are mounted at their respective, opposite ends. Calandria extensions 58 project downwardly from at least selected ones of the calandria tubes 56 and connect to corresponding ones of the mounting means 36 and 38 for the upper ends of the tube guides 28 and 32, as specifically illustrated in FIG. 1 for the upper mounting means 36 associated with the RCC rod guide 28. Extending upwardly beyond the upper calandria plate 54 and particularly within the dome 12a of the vessel 12, there are provided a plurality of flow shrouds 60 respectively aligned with the calandria tubes 56. A corresponding plurality of head extensions 62 is aligned with the plurality of flow shrouds 60, with respective adjacent ends thereof in generally overlapping relationship. Control rod cluster (RCC) displacement mechanisms 64 and water displacement rod cluster (WDRC) displacement mechanisms 66 are associated with the respective head extensions 62, flow shrouds 60 and calandria tubes 56 which, in turn, are respectively associated with the respective clusters of radiation control rods 30 and water displacment rods 34. Particularly, the RCC and WDRC displacement mechanisms 64 and 66 connect through corresponding lines to the respective clusters of radiation control rods and water displacement rods 30 and 34, to control the position thereof and, particularly, to selectively lower same through corresponding openings provided therefore in the upper core plate 19 into surrounding relationship with respectively associated fuel rod assemblies 20. While the particular control function is not relevant to the present invention, insofar as the control over the reaction within the core is effected by the selective positions of the respective rod clusters 30 and 34, it is believed that those skilled in the art will appreciate that moderation or control of the reaction is accomplished in accordance with the extent to which the control rod cluster 30 is inserted into the core and with the effective water displacement adjustment which is achieved by movement of the water displacement rods 34. The general configuration and arrangement of the modular formers, in each of the lower, mid, and higher banks of modular formers 40, 42 and 44, is substantially identical, the principal differences being the vertical height of each thereof in the different banks and, as later detailed, the relative radial depth and effective arcuate segment encompassed thereby within a given bank. Thus, with concurrent reference to FIGS. 1 and 2, the latter being a cross-sectional view taken along the line 2--2 in FIG. 1, the plan view of the bank 42 of modular formers is illustrative as well of a plan view of the banks 44 and 40. Moreover, as will become clear, the modular formers of each bank 42 are identical in configuration and assembly as to the upper and lower surfaces thereof, and thus FIG. 2 illustrates a plan view from the lower surface of each of the banks, 40, 42 and 44 as well. As before noted, only a single RCC tube guide 28 and single WDRC tube guide 32 are shown in FIG. 1, it having been noted that a large number thereof are disposed in closely adjacent relationship in an array extending substantially throughout the entire cross-sectional area of the inner barrel assembly 24. In FIG. 2, several WDRC rod guides 32 are shown along with interspersed RCC rod guides 28, the guides 28 and 32 having a complementary configuration permitting an interdigitized and alternating geometric pattern thereof, somewhat of a honeycomb in nature, which occupies substantially the entire cross-sectional area within the cylindrical sidewall 26 of the inner barrel assembly 24. Due to the generally square, cross-sectional configuration of the WDRC rod guides 32, and the generally X-shaped cross-sectional configuration of the RCC rod guides 28, the array of alternating, or staggered RCC and WDRC rod guides 28 and 32 has a generally rectangular perimeter. This necessarily results in arcuate segment spacings in the peripheral regions between the generally rectangular perimeter edges of the array of rod guides 28 and 32 and the circular interior circumference of the cylindrical sidewall 26. Moreover, the peripheral regions differ in configuration and size. Particularly, for the square, cross-sectional configuration of the WDRC rod guides 32, a different spatial relationship and configuration is defined between the rod guides 32 of a lowermost row as seen in FIG. 2 having the respective diagonals thereof extending in parallel with a diameter D1 and the adjacent interior circumferential surface of the sidewall 26, compared to that configuration and size of the peripheral region lying between a row of rod guides 32 having a pair of sidewalls which are parallel to the 45.degree. displaced diameter D2. Accordingly, the modular former 70 disposed symmetrically about the diameter D1 has a different configuration than that of the modular former 80 disposed symmetrically about the diameter D2. It will be apparent, of course, that for other cross-sectional configurations of the guides 32 (e.g., rectangular or other polyhedron structure), that other geometrical relationships would exist, defining differing peripheral regions between the boundaries of the array and the interior circumference of the cylindrical sidewall 26. Since interchangeability, modularity, and uniform array characteristics are usually desired, the rod guides 32 typically will have a cross-sectional structure which is symmetrical about one or more axes (e.g., an equal number of sides respectively disposed in paired, parallel relationship). The resulting array perimeter defines a corresponding, repeating succession of peripheral regions of differing configurations. The modular formers accordingly are shaped to correspond to these differing configurations. Thus, for the array of FIG. 2, there are two different configurations of modular formers 70 and 80, which repeat in alternating succession at 45.degree. angular segments. Specifically, modular formers 70 of the first type are disposed symmetrically about the diameters D1 and D3, and modular formers 80 of the second type are disposed symmetrically about the respective 45.degree. -related diameters D2 and D4, in succession. FIG. 3 is a perspective view of a typical modular former 80 of the second type, but serves as well to illustrate the basic construction of the modular formers 70 of the first type. The modular former 80 includes an upper former plate 81 and a lower former plate 82, which are identical in configuration, and first and second vertical columns 83 which likewise are identical in configuration, having generally U-shaped cross-sections. With concurrent reference to FIGS. 3, 4(a) and (4b), each of the U-shaped vertical columns 83 includes tabs 85 extending from the respectively opposite ends thereof, and which are received through corresponding slots 86 in the respective upper and lower former plates 81 and 82. A weld bead 87 is formed on the remote exterior surfaces of the respective former plates 81 and 82 at their junctures with the tabs 85, as seen in FIG. 3. As before noted, the first type of modular former 70 has the same basic construction as the second type of modular former 80, but is configured differently in accordance with the different peripheral region in which it is employed, generally being more shallow. This can readily be appreciated by comparing FIG. 5(a), comprising an end elevational view of a vertical column 73 as employed in the first type of modular former 70, with the end elevational view in FIG. 4(a) of the vertical column 83 of the second type of modular former 80. The vertical column 73 includes corresponding tabs 75 by which it is mounted through slots 76 to its corresponding upper and lower former plates 71 and 72, as illustrated in FIG. 5(b). Whereas each of the identical former plates 71, 72 and the identical former plates 81, 82 has an identical radius of curvature of its outer arcuate segment edge 70', 80', the respectively corresponding inner, chordlike edges 70", 80" are provided with mating contours for accommodating the elements of the array respectively adjacent thereto. Thus, the modular formers 70 of the first type have relatively larger arcuate segment edges 70' and correspondingly, longer inner chordlike edges 70", with relative shallower contours for defining a mating relationship with the diagonally protruding corners of the juxtaposed, or adjacent rod guides 32, the latter being separated further by the rod guides 28 which are interposed therebetween. Conversely, the former plates of the second type of modular former 80 have relatively shorter outer arcuate segment edges 80' and inner chordlike edges 80"; and the latter are more deeply notched or contoured to accommodate the more closely spaced and more sharply outwardly protruding portions of the rod guides 28. Thus, the respective, inner chordlike edges 70" and 80" have contours which mate with the effective contours of the peripheral edges of the array of guides 28 and 32 juxtaposed therewith. It likewise will be appreciated that the interposed, or alternating, relationship of the guides 28 and 32 and the nature of the alignment thereof within the array will define the contours of the peripheral edges of the array and correspondingly the mating dimensions and contours of the inner chordlike edges of the former plates. Thus, the inner edges 70" are relatively longer in view of the parallel relationship thereof to the alignment axis of the diagonally oriented guides 32 having the guides 28 interspersed therebetween; conversely, the inner edge 80" is parallel to an alignment axis of the guides 32 which is parallel to a pair of parallel edges of the rod guides 32. As is also apparent, the shallower depth of the U-shaped vertical channels 73 relative to the greater depth of the channels 83 corresponds to the mating contours of the inner edges 70" and 80" of the respectively associated modular formers 70 and 80. Each of the modular formers 70 and 80 is secured to the cylindrical sidewall 26 by cantilever attachment elements 90, which are shown in more detail in FIG. 6(a), 6(b) and 6(c), respectively comprising plan, side elevational and end elevational view thereof. The cantilever attachment element 90 preferably is integrally formed to include a shank portion 91 and a mounting block 92 in common axial alignment, the block 92 being undercut on its lower surface to define a pair of legs 93. With reference to FIG. 3, weld lines 94 are formed between the legs 93 and the corresponding surface of the former plate 81. The significance of the legs 93 is that full penetration weld lines 94 readily may be provided, optimizing the weld attachment. The elements 90 are correspondingly attached to the lower former plate 82. FIG. 7 is an elevational, partially cross-sectional view taken along the line 7--7 in FIG. 2 and illustrates the attachment of a modular former 80 to the cylindrical sidewall 26 through use of the cantilever attachment elements 90. The sidewall 26 preferably includes annular grooves 95 positioned at the desired height of the former plates 81 and 83 for a given bank of modular formers 40, 42 and 44, within which the respective outer, arcuate edges 80' of the former plates 81 and 82, respectively, are received. Further, holes 96 are formed through the sidewalls 26 through which the shanks 91 of the cantilever attachment elements 90 are received and which then are welded in place from the exterior of the sidewall 26, as illustated by weld lines 97. With reference to FIG. 2, it will be appreciated that the holes 96 provided in the sidewall 26 for the cantilever attachment elements 90 of a given former extend in parallel relationship relative to the associated, symmetrically related diameter. Moreover, the cantilever attachment elements 90 are secured to the respective former plates 71 and 81 as seen in FIG. 2 so as to dispose the mounting blocks 92 at a common radius less than that of the sidewall 26 such that the outer extremities of the shanks 91 are substantially flush with the outer surface of the sidewall 26. FIG. 2 shows the elements 90 attached to the upper former plates 71 and 81 and affixed to the sidewall 26. It will be understood that the elements 90 attached to the corresponding, lower former plates 72 and 82 (not seen in FIG. 2) are correspondingly affixed to the sidewall 26. The modular formers 70 and 80 of the invention, assembled and installed as the three banks 40, 42 and 44 shown in FIG. 1, thus provide a succession of six former plates at corresponding, six displaced vertical elevations within the inner barrel assembly 24. The modular construction of the formers is of great significance, both structurally and as to their functional performance during subsequent operation of the reactor 10. Specifically, the entirety of each of the modules 70 and 80 may be assembled externally of the inner barrel 26, including welding of the cantilever attachment elements 90 thereto. Because of the parallel axial relationship of the cantilever attachment elements 90, and the corresponding holes 96 provided therefore in the sidewall 26, each of the modules 70 and 80 readily may be inserted into position and then welded to the sidewall 26 from the exterior of the latter, greatly facilitating the assembly operation. The vertical columns within each module afford substantial strength and rigidity to the former plates which they join. By way of example, individual former plates, if mounted individually (or as a continuous annular ring) in a cantilever type mount arrangement, would not have nearly the stability or rigidity as is achieved through the modular construction of the formers of the present invention. Any such continuous, annular former, moreover, would be incapable of being fully assembled prior to insertion into the barrel, and specifically, could not permit the exterior welding operation by which the modular formers of the invention may be attached to the barrel. During operation, the modular formers 70 and 80 provide the required pressure drop to cause the core outlet flow to approach an axial flow condition with uniform distribution in the rod guide region within the inner barrel assembly 24. The structural configuration of each module, comprising the vertical columns joined by welding to the former plates, affords a very stiff, i.e., rigid, yet relatively lightweight structure; this is highly important, so as to reduce the potential of flow-induced vibration and seismic loading on the inner barrel assemblY 24. The use of modules, moreover, as distinguished for example from a continuous former plate extending throughout the inner circumference of the sidewall 26, inherently reduces thermal stresses which otherwise could be encountered between such a unitary former plate and the sidewall 26. Moreover, because of the modular construction, the attachment points for a given module are relatively closely spaced and, thus, the amount of elastic deformation required to relieve stress due to differential thermal reaction of the former plate and the sidewall 26 is reduced. Additionally, the circular cross-section of the shank porton 91 of each cantilever attachment element 90 is capable of deflection, thereby permitting differential thermal expansion between the former plate and the sidewall 26 without introducing overstressing. The welded assembly of each module is significant, since both the column attachment welds and the module attachment welds are placed in sheer, such that a complete and clean sheer across the entire section of the weld must occur before separation of the mating parts could occur. By way of illustration and exemplification but not limitation, a specific system having three banks of modular formers in accordance with the invention is now described with reference to the particular structural dimensions. In one specific design, the cylindrical sidewall 26 of the inner barrel assembly 24 has a diameter of approximately 169 inches and an axial height of approximately 176 inches between the upper core plate 19 and the lower calandria plate 52. The upper and lower former plates 81, 82 and 71, 72 are formed of steel of approximately one inch thickness and the associated vertical columns 73 and 83 are formed of steel sheet of approximately one-half inch thickness. The U-shaped columns 73 are approximately four inches in the depth of the relatively shallow U-shaped portion. The deeper U-shaped channels 83 are of a width of approximately 16 inches with a depth of the U-shaped portion of approximately 6.5 inches. The height of the vertical columns 73 and 83 is approximately 15 inches for the bottom bank 40 and approximately 31 inches for the upper banks 42 and 44. The lower bank 40 is displaced approximately 15 inches from the upper core plate 19 and a vertical spacing of approximately 31 inches is provided between each of the respective banks 40 and 42 and banks 42 and 44. While the foregoing is illustrative of a specific implementation, it is to be understood that other sizes of formers, elevational spacings thereof, and the like, may be dictated by the particular configuration of, and fluid dynamics within a given reactor. It also will be appreciated that while a preferred configuration of the modular formers has been disclosed, the particular contouring thereof and the like will be dependent upon the character of the rod guides and the assemblage thereof into an array. Further, whereas the preferred form of a modular former includes two parallel columns such as 73, 73 and 83, 83 for the respective modules 70 and 80, other configurations may dictate modification of the specifically illustrated, preferred modular formers; illustratively, and with reference to FIG. 3, a unitary column 83 may be suitable in certain applications and by contrast multiple columns 83 may be more appropriate in other applications. In any such variations, it is important that the column provide both rigid vertical separation and radially displaced multipoint connections with the parallel former plates, so as to afford lateral stability and rigidity. Accordingly, it is believed apparent to those of skill in the art that the modular formers of the present invention satisfy a signficant need in assuring stablization of core output flow through the inner barrel of a nuclear power generator having a complex and advanced design of the type herein disclosed. Fabrication costs of the module are minimized due to standardization of parts and the capability of automated assembly of each module as a unit, prior to installation in the reactor; further, final assembly welding of each module to the inner barrel sidewall may be accomplished expeditiously. These and other advantages will be apparent to those skilled in the art, as will numerous modifications and adaptations of the particular modular formers of the invention as herein disclosed. Accordingly, it is intended by the appended claims to cover all such modifications and adaptations of the invention as fall within the true spirit and scope of the appended claims.