Patent Number: 047160136
Section: description

DETAILED DESCRIPTION OF THE EMBODIMENT The apparatus shown in the drawings is a nuclear reactor 11 including a pressure vessel. The vessel includes a circularly cylindrical body 15 closed at the bottom by a hemispherical bowl 17. The vessel has a flanged dome-shaped head 19 which is bolted or welded to the body at the flange 21. The body 15 has a plurality of inlet nozzles 23 and a plurality of outlet nozzles 25 distributed around its periphery. Typically, there are four inlet nozzles 23 interspaced in pairs between four outlet nozzles 25. The inlet nozzles 23 are shown in the drawings at the same level as the outlet nozzles 25. Reactors in which the inlet nozzles are at levels above or below the outlet nozzles are within the scope of equivalents of this invention. In the lower region of body 15 there is a nuclear core 27. This core includes fuel assemblies 29 including fuel rods 32 and thimbles 31 for receiving control rods (not shown). The fuel assembles 29 are mounted between upper core plate 33 and lower core plate 35. The control rods are mounted in clusters and include rod clusters (RCC's), which have a high absorption cross-section for neutrons, grey rod clusters, which have a lower absorption cross-section for neutrons, and water-displacement rod clusters (WDRC's). The RCC's serve to shut down the reactor or to reduce its thermal power output. The grey clusters serve for load follow. The WDRC's displace the coolant in thimbles which do not receive RCC's or grey rod clusters. Such displacement takes place during the earlier part of the fuel cycle of the reactor, typically during about the first 60% of the fuel cycle. The upper part of the body 15 contains the upper internals 37 and the calandria 39. All fixed members above the core are sometimes referred to as "upper internals" in the nuclear art. In this case it appears desirable in the interest of clarity to refer to the calandria as a separate member. The upper internals 37 include the vertical guides 41 (FIG. 3A) for the RCC's and grey control-rod clusters, and the vertical guides 43 for the WDRC's. The RCC's and grey control-rod clusters are mounted on cruciform structures 40 and the guides 41 for these rods are hollow cruciform cans. The guides 43 for the WDRC's are of generally rectangular or square cross-section with their corners truncated, and strictly may be described as octagonal cans. The sides 38 of the WDRC guides 43 are encompassed by projecting arms of four RCC or grey-rod guides 41 and extend parallel to these arms. Plates 45 having coaxial holes 47 extend vertically internally along the guides 43. The plates 45 serve as supports for the WDRC's which are guided along the holes 47. The vertical side walls 49 and 51 (FIG. 1) of the guides 41 and 43 are substantially imperforate but the guides are open at their tops and bottoms. There may be small holes 53 and 55 (FIG. 1) near the tops of guides 41 and 43 for the purpose of stabilizing or equalizing the pressure of the coolant. While reactors in which the walls 49, 51 of the guides 41, 43 are substantially imperforate has unique advantages, there may be situations in which these walls may be perforate and reliance is placed on the pressure of the coolant to confine the coolant to substantially reduce flow. Perforate guides are shown in application Ser. No. 490,097, filed concurrently herewith to Luciano Vernosei for "Nuclear Reactor", and assigned to Westinghouse Electric Corporation. Reactors in which perforate guides are used is within the broader scope of equivalents of this invention. The calandria 39 (FIG. 6) is disclosed in Veronesi. It includes a lower generally horizontal support plate 54 (FIG. 4) and an upper generally horizontal support plate 56 (FIG. 5). Between these plates 54 and 56, generally vertical hollow members 58 are supported. The hollow members 58 typically are tubes of circular cross-section. They are secured by fillet welds 60 (FIG. 6) in counterbores 62 in the upper plate 56 and are screwed to lower plate 54. The hollow members 58 are slightly tapered where they join the lower plate 54. The lower plate 54 has holes 64 which typically have a racetrack or oval shape. Typically each hollow member 58 is surrounded by oval holes 64. The plate 54 also has pin holes 71 which serve to center the guides 41 and 43. The guides have pins (not shown) at the top which enter holes 71. The lower and upper plates 54 and 56 are circularly cylindrical and the hollow members 58 are substantially uniformly spaced in the circularly cylindrical volume defined between the plates 54 and 56. The volume between the plates is enclosed in a shell 66 (FIGS. 1, 6). The shell 66 is of composite structure including a short annular strip 68 and a longer annular strip 70. The strip 68 is welded between the upper plate 56 and the longer strip 70. The longer strip 70 contains openings 72 which are coaxial with the openings 61 in the barrel 57 and which are spaced to mate with the opening 61. The shell 66 is closed opposite the inlet nozzles 23 (FIG. 1). A supporting cylinder or shell 74 extends from the upper support plate. The cylinder 74 is composite including a lower cylindrical strip 76 and an upper member including a flange 78. (See also FIG. 1.) The strip 76 is welded at its lower end to the upper plate 56 of the calandria and the flanged member 78 is welded to the upper end of the strip 76. The cylinder 74 is coextensive with the shell 66. The upper internals 37 and the calandria 39 are contained in a barrel or shell 57 (FIG. 2). The barrel 57 is circularly cylindrical and it has holes 61 below the top which are shaped to mate with the rims of contiguous outlet nozzles 25 and with the holes 72 in the shell 66 of the calandria. The holes 61 are coaxial with the outlet nozzles 25. The barrel 57 has a flange 65 at the top; at its lower end the barrel 57 supports the upper core plate 33. The guides 41 and 43 are closely packed except near the periphery. Coolant flowing from the core 27 into the spaces between the guides therefore has a high velocity and tends to flow towards the periphery. The pressure of this coolant decreases from the bottom of the upper internals 37 to the top. To suppress transverse flow of coolant under the pressure between the closely spaced guides 41 and 43 and the relatively free volume at the periphery of the upper internals 39, horizontal former plates (FIGS. 1, 2) extend along the barrel 57. The plates 67 are spaced a short distance from the outer boundary of the upper internals 37. The pressure of the coolant is thus distributed so that the coolant outside of the guides 41, 43 flows upwardly about the guides and upwardly through the gaps between the formers 67 and the boundary 69 of the guide assembly (FIG. 3). The core 27, upper internals 37 and calandria 39 are enclosed in an outer barrel 81 (FIG. 1). The lower core plate 35 is mounted on the lower end of this barrel. At its upper end the barrel 81 has a flange 85. The barrel has openings shaped to mate with the boundaries of the openings 61 in the barrel 57 and coaxial with the contiguous outlet nozzles 25. The core 27, the upper internals 37, and the calandria 39 are mounted generally coaxially. The upper core plate 33 has pins 87 (FIGS. 1, 2) which engage and center the fuel assemblies 29. The cylinder 76 and the shell 60, the barrel 57 and the barrel 81 are mounted generally coaxially with each other and with the core 27, the upper internals 37 and the calandria 39. The flange 85 rests on a ledge 89 in the inner surface of body 15. The flange 65 of barrel 57 is above flange 85 and a spring (not shown) is interposed between these flanges. The flange 78 is disposed upon flange 65. The shell 66, the barrel 57 and the barrel 85 are oriented circumferentially so that the boundaries 91 and 93 of the openings 72 and 61 mate with each other, the boundaries 93 (FIG. 1) of the openings 61 in barrel 57 mate with the boundaries 95 of the openings in barrel 81, and the boundaries 95 of the openings in barrel 81 mate with the inner rims 97 of the outlet nozzles 25. The annulus 99 between the barrel 81 and the body 15, usually referred to as the downcomer, is in communication with the inlet nozzles 23 and conducts the coolant. The coolant which flows in through the inlet nozzles flows down along the annulus 99 FIG. 1 into bowl 17, thence up through the core 27 and through the upper internals 37 into the calandria 39 where it flows generally transversely to and through the outlet nozzles 25. The joints between the boundaries 91, 93 and 93, 95 and between the boundaries 95 and the rims 97 form pressure-tight seals at the outlet nozzles so that there is minimal by-pass of flow of the coolant from the annulus 99 through the outlet nozzles 25. As shown, the outflow channels of the outlet nozzles 25 are just above the upper internals and substantially at the level of the hollow members 58 of the calandria 39 so that the coolant which passes through the calandria flows directly out of the outlet nozzles 25. The lower plate 54 of the calandria 39 is mounted contiguous to the top of the upper internals 37 and the coolant flows into the calandria through the openings in guides 41 and 43, through the spaces between these guides and through the gaps between the formers 67 and the periphery 69 of the upper internals. The calandria 39 serves as upper support for the upper internals. In assembling the reactor 11, the head 19 is pressed downwardly so that its flange 21 engages the top of body 15. The flanges 72, 65 and 85 and the spring (not shown) between flanges 65 and 85 are compressed. The flange 21 is bolted or welded pressure-tight to the body 15. The drive rods 101 (FIG. 5) for the control rods pass through the hollow members 58 of the calandria and are protected by these members. By operation of the drive rods 101, the control rod spiders are moveable upwardly or downwardly between the bottom of the lower plate 54 of the calandria and the top of the upper core plate 33. The plates 54 and 56 and the hollow members 58 of the calandria are composed of stainless steel. The outlet nozzles 25, typically, are about 40 inches in diameter. The hollow members 58, typically, have an outer diameter of 31/2 inches, an inner diameter of 21/4 inches and a length of about 50 inches. With the hollow members 58 of this structure supported at both ends by the plates 54 and 56, the stresses produced by the transverse flow of the coolant even at a velocity of 40 ft./sec. is minimized and failure of the hollow members is precluded. While preferred embodiments of the invention have been disclosed herein, many modifications thereof are feasible. This invention is not to be restricted except insofar as is necessitated by the spirit of the prior art.