Patent Number: 041397789
Section: description

DESCRIPTION OF THE PREFERRED EMBODIMENT In nuclear reactor systems it is necessary to store fuel assemblies before and after the fuel assemblies are used in the nuclear reactor. The invention described herein provides apparatus capable of storing such fuel assemblies without the fuel assembly developing unacceptable stresses therein. Referring to FIG. 1, a typical ductless fuel assembly 10 comprises fuel elements 12. Fuel elements 12 may be hollow cylindrical metallic tubes filled with nuclear fuel as is well known in the art. Fuel elements 12 are held at their upper end by upper end support 14 and at their lower end by lower end support 16. Upper end support 14 and lower end support 16 are metal supports that are capable of maintaining proper alignment of fuel elements 12 within fuel assembly 10 and of providing a mechanism for attachment during transportation and reactor operation. Both upper end support 14 and lower end support 16 have openings 18 therein for accommodating alignment pins. During storage, fuel assembly 10 is supported from its upper end by clamp 20 which is a metal support conforming to the shape of upper end support 14. Once fuel assembly 10 has been placed in clamp 20 by typical fuel handling apparatus, clamp 20 may be made secure by tightening the winged nut and bolt arrangement 22 or other suitable fastening means. Clamp 20 is attached at the end opposite nut and bolt arrangement 22 to center post 24 by means well known in the art such as by sleeve 26 which may be welded to center post 24. Center post 24 may be a hollow cylindrical metal column supported vertically by its attachment to base 28 along with supporting metal struts 30. Base 28 may be either a metal plate fixed to the floor of the storage facility or it may be the floor itself. Center post 24 has four symmetrically disposed clamps 20 arranged in conjunction with struts 30 such that at least four fuel assemblies 10 may be supported from one center post 24. While fuel assembly 10 is supported from its upper end support 14 by clamp 20, the lower end support 16 rests on swivel base 32. Referring now to FIG. 2, swivel base 32 comprises first plate 34, second plate 36, third plate 38, ball 40, circular pins 42, and diamond pins 44. Third plate 38 may be a rectangular carbon steel plate approximately one inch thick and fastened to base 28 by appropriate means such as first screws 46. Second plate 36 is a rectangular carbon steel plate approximately one inch thick with its corners removed to expose the corners of third plate 38. Second plate 36 has a first hole 48 drilled in the center thereof that is complimentary to a similar center drilled second hole 50 in third plate 38 for accommodating a hard steel ball 40. Ball 40 which may be approximately 1.5 inches in diameter rests in second hole 50 of third plate 38 while second plate 36 rests on ball 40 such that ball 40 fits into first hole 48. When second plate 36 rests on ball 40 in this arrangement, second plate 36 is separated from third plate 38 by a gap 52 which may be approximately 0.125 inch wide. A foam rubber or urethane sheet 54 with a hole therein corresponding to first hole 48 and second hole 50 may be inserted into gap 52 between second plate 36 and third plate 38 so as to prevent foreign material from becoming lodged between the plates. Second plate 36 is, thereby, capable of moving relative to third plate 38 by pivoting or rotating on ball 40. A first plate 34 which may be manufactured of nylon or stainless steel and may be approximately 0.25 inch thick is attached to the top of second plate 36 by means well known to those skilled in the art such as second screws 56. First plate 34 provides a mechanism for isolating contact of lower end support 16 from second plate 36 to thereby avoid corrosion of fuel assembly 10 because contact of fuel assembly 10 with the carbon steel of second plate 36 may cause corrosion of fuel assembly 10. Hardened round pins 42 and diamond pins 44 are press fitted through first plate 34 and into second plate 36. Round pin 42 and diamond pin 44 are capable of fitting into openings 18 in lower end support 16 so as to engage lower end support 16 and support the weight of fuel assembly 10. Round pin 42 has a diameter 58 which may be approximately 0.8 inch and diamond pin 44 has a length 60 across farthest tips which is equal to diameter 58 while line 62 denotes the distance across the short tips of diamond pin 44 which is less than diameter 58. When fuel assembly 10 is placed on swivel base 32, a round pin 42 engages an opening 18 while a diamond pin 44 located across the center of swivel base 32 from the round pin 42 engages a similar opening 18 thereby preventing rotation of fuel assembly 10 with respect to plates 34 and 36 of swivel base 32. Line 62 being shorter than length 60 allows a fuel assembly 10 to be positioned on a round pin 42-diamond pin 44 set even though the corresponding openings 18 are separated by a distance slightly different from the distance between the pins while still preventing rotation of fuel assembly 10. A first round pin 42-diamond pin 44 set is located on first plate 34 to accommodate a fuel assembly 10 having a 14 .times. 14 array of fuel elements while a second set of pins are located at 45.degree. from the first set so as to accommodate a fuel assembly 10 having a 15 .times. 15 array of fuel elements 12 thereby providing swivel base 32 with the capability of supporting either type of fuel assembly. Furthermore, first plate 34 and second plate 36 have a centered hole 64 therethrough that allows clamp 20 to be aligned with the center of swivel base 32 by plumb bob or other such methods. When a typical fuel assembly 10 has been placed into clamp 20, lower end support 16 rests on swivel base 32 with a diamond pin 44 and corresponding round pin 42 engaging openings 18 of lower end support 16. While in this position the fuel assembly 10 may not be completely vertically aligned because of misalignment in clamp 20 or for other common reasons such as thermal bending. Since a typical fuel assembly 10 may be approximately 156 inches in length and weigh approximately 1500 pounds, this slight misalignment may cause severe stresses in the fuel assembly. However, because the fuel assembly 10 rests on swivel base 32, first plate 34 and second plate 36 together move relative to third plate 38 by revolving on ball 40 thereby allowing fuel assembly 10 to become aligned in a nonstressed position. When so moving, second plate 36 may either compress sheet 54 or allow sheet 54 to expand slightly. While in the prior art, a slight misalignment may have produced a high stress level in a fuel assembly without a swivel base thereby approaching the situation of a long slender column with two clamped ends, the present invention approaches the condition of a column with one end clamped and the other end pivoted. Therefore, the invention provides a fuel assembly storage rack having a swivel base with plates capable of relative motion for supporting fuel assemblies while minimizing the stresses in the fuel assembly. While there is described what is now considered to be the preferred embodiment of the invention, it is, of course, understood that various other modifications and variations will occur to those skilled in the art. The claims, therefore, are intended to include all such modifications and variations which fall within the true spirit and scope of the present invention. For example, ball 40 may be replaced with a hemispherical member that would rest with its flat side on third plate 38 while its hemispherical side would extend into first hole 48.