Patent Number: 046541853
Section: description

DETAILED DESCRIPTION Referring now to FIG. 1, a nuclear reactor 1 includes a pressure vessel 3, generally of cylindrical shape having an outer pressure resistant wall 5 that is closed at its bottom by a bottom wall 7 of hemispherical contour. The vessel is closed at the top by a flanged dome-shaped head 9, which is secured, such as by bolts, to the top edge 11 of the pressure resistant wall 5, preferably seated in a channel 13 about the wall 5. The pressure resistant wall 5 has a plurality of inlet nozzles 15 and a plurality of outlet nozzles 17 distributed about its periphery, with four of each of such nozzles usually provided. A nuclear core 19 is supported in the lower region of the vessel 3, the core being supported in spaced relationship to bottom wall 7 by an outer barrel 21, the outer barrel 21 having a flange 23 which rests on a ledge 25 in the inner surface of the pressure resistant wall 5. The core 19 includes a series of fuel assemblies 27 and thimbles 29 for receiving control rods (not shown), which are mounted between a lower core plate 31 and upper core plate 33. The control rods, as is known, may contain rod clusters of high or low absorption cross-section for neutrons, and water displacement rod clusters, and serve to reduce the thermal power of the reactor, or otherwise control the same, or to shut down the reactor. In the upper region of the vessel 3, the upper internals 35 and a calandria 37 are provided. The upper internals 35 include vertical guides 39 for control rods and vertical guides 41 for water displacement rods. The calandria 37 has a lower horizontal support plate 43 and an upper horizontal support plate 45, with a series of generally vertical hollow members 47 therebetween. The hollow members 47, generally of circular cross-section, are secured by welds to the upper horizontal support plate 45, and pass through the lower hollow support plate 43. The lower and upper horizontal support plates 43 and 45 are generally circular, with the hollow members 47 substantially uniformly spaced therebetween. The plates 43 and 45 are surrounded by a shell 49. The shell 49 is situated within an inner barrel 51, which inner barrel also contains the upper internals 35, that is supported by a flange 53 that rests on flange 23 of the outer barrel 21. Shell 49 also has a flange 55 about the top edge thereof which rests on flange 53 of inner barrel 51. The shell 49 has openings 57 therein which communicate with openings 59 in the inner barrel 51, which openings 59 in turn communicate with openings 61 in outer barrel 21, which finally communicate with the outlet nozzles 17. Inner barrel 51 supports the upper core plate 33 and horizontal plates 63 are provided along the inner barrel 51. The core 19, upper internals 35 and calandria 37 are mounted generally coaxially within the vessel 3, while the shell 49, inner barrel 51 and outer barrel 21 are also mounted generally coaxially therein. An annulus 65 between the outer barrel 21 and the pressure resistant wall 5 provides for communication between the inlet nozzles 15 and the lower end of the core 9. Drive rods 67 from the control rods extend through head penetrating adaptors 69 in the dome-shaped head and then through the hollow members 47 of the calandria 37. The drive rod mechanisms 71 may be contained within an enclosure formed by walls 73 and a cover (not shown), the walls welded to the outer end 75 of the dome-shaped head 9. Coolant enters through inlet nozzles 15 and flows downwardly through annulus 65 to bottom wall 7 and then upwardly through the core 19, upper internals 35 and into the calandria 37, from which it flows transversely to and outwardly from the outlet nozzles 17. Joints between the openings 57 in shell 49, openings 59 in inner barrel 51 and openings 61 in outer barrel 21 are provided to form pressure-tight seals at the outlet nozzles 17 so that there is minimal or no bypass flow of coolant from the annulus 65 directly to the outlet nozzles 17. In the arrangement described, an area of unused open space 77 is present in the dome-shaped head 9, into which some coolant will flow from the calandria 37. Because of the existence of this open space 77 long drive shafts are required, which are usually of two-piece assemblies. Since there is some flow of coolant through space 77, flow shrouds are best used to protect the drive shafts. Such flow of coolant into the space 77 also requires the use of more coolant in the reactor than would be required without the presence of such a space. Referring now to FIGS. 2 and 3, the improved deep beam head 81 of the present invention is illustrated. A calandria 37 is disposed in the upper region of the pressure vessel 3 of an improved nuclear reactor 82. The reactor 82 comprises the components of reactor 1 aforedescribed, except in the region above the inlet nozzles 15 and outlet nozzles 17, such as the upper internals 35 with control rod guides 39, displacement rod guides 41, and horizontal plates 63, above the core (not shown), all of which are supported in outer barrel 21 and inner barrel 51. The calandria 37 contains a lower horizontal support plate 43, upper horizontal support plate 45, hollow members 47, and outer shell 49. The upper support plate 45, as shown, is in the form of a sealing plate 83 which, at its outer periphery 85, rests on the top edge 11 of the pressure resistant wall 5, and seals the top opening of the pressure vessel 3. A ring member 87 is provided about the upper periphery of the sealing plate 83, and is secured to the outer pressure resistant wall 5 such as by bolts 89 which pass through apertures 91 in the ring member 87 and apertures 93 in the sealing plate 83, and are fixed in the pressure resistant wall 5, with nuts 95 securing the ring member 87, through the bolts 89, to the pressure resistant wall 5. A plurality of spaced reinforcing members 97 are provided atop of the sealing plate 83, the reinforcing members 97 extending across the sealing plate and being secured to the ring member 87 such as by welds 99. A plurality of transverse cross-members 101 atop the sealing plate 83 extend across the sealing plate 83 and are secured, as by welds 103, to the reinforcing members 97, with the end portion of said plurality of cross-members also secured to the ring member 87 by welds 105. As illustrated in the drawings, the reinforcing members 97 and transverse cross-members 101 may have a raised central portion relative to the end portions thereof to provide additional strength. The number of reinforcing members 97 and cross-members 101 used may vary dependent upon their thickness and heighth and, as indicated in FIG. 4 may extend across the sealing plate 83 between each row of drive rod mechanisms, every other row of drive rod mechanisms, or less frequently. The specific quantity of such reinforcing members and cross-members would be that sufficient to provide the resistance to pressure of the sealing member needed for a particular reactor design. For example, with a sealing plate of a thickness of about six inches, reinforcing members and cross-members of a heighth of about 12-15 inches and a thickness of about two inches could be used between every other row of drive mechanisms. An enclosure may be provided to enclose the drive rod mechanisms 71, the enclosure having vertical walls 107, with the vertical walls 107 secured by welds 109 to the ring member 87. Securing means, such as bolts 111, with the heads thereof disposed in a recess 113 in the underside of the sealing plate 83, are provided to secure the ring member 87 and sealing plate 83 together. Since the reinforcing members 97 and cross-members 101 are secured to each other and to the ring member 87, but not to the sealing plate 83, the calandria 37 is readily separable from the same by removal of the bolts 111. An O-ring 115 is also provided between the top edge 11 of the pressure vessel wall 5 and the flange 85 of the sealing plate 83 to provide a seal therebetween. Welds 117 are also used to seal the drive mechanism system to the sealing plate 83 and preclude any leakage therebetween. The incorporation of the sealing plate 83 and upper horizontal support plate 45 as a single unit provides a number of advantages. The elimination of the open space between the upper support plate of the calandria and the dome-shaped head conventionally used enables the use of simpler, shorter one piece drive rod assemblies instead of two piece drive assemblies. Also, there is no need for flow shrouds to protect the drive rods, as is generally needed where the upper open area is present with coolant passing therethrough. Alignment problems are also reduced since the calandria upper support plate with the hollow members and the mechanism pressure housing are unitary. Concerns about buckling of long drive rod assemblies during drive mechanism actuation are eliminated since shorter assemblies can be used. The construction enables the use of mechanism housings of the same length, due to removal of a dome-shaped head, resulting in economies of scale. Also, the primary coolant water volume in the reactor is reduced since no open space for primary coolant is present above the calandria between the conventional upper horizontal support plate of the calandria and the conventional dome-shaped head. Maintenance and disassembly of the reactor is improved by the present construction. The calandria, since it is secured to the ring member 87 by bolts 111 through the sealing plate 83, is removable with the vessel head, exposing the upper internals 35 of the reactor for maintenance or inspection. Also, because shorter drive rods are usable, a smaller pit for storage of the upper internals could be used. By avoiding the open space normally present between the calandria and the conventional dome-shaped head, the length of the pressure vessel 3 is reduced, which improves the strength of the same and reduces machining necessary. Also, a smaller containment vessel could be used to contain the reactor. The shorter construction would reduce the required containment and crane height. In addition, the seismic capability is improved because of the overall shorter length of the reactor and the ability to weld the vertical walls 107 of the enclosure, or internals head package shroud, directly to the ring member 87. There is thus provided a deep beam head for a nuclear reactor which, by being formed as a part of a calandria in the upper portion of the reactor, provides benefits that are not achievable when the conventional dome-shaped heads are used on such reactors.