Patent Number: 052157075
Section: description

DETAILED DESCRIPTION OF THE INVENTION Referring to FIG. 1, a thimble tube shroud 1 is disposed in a nozzle 2 of a nuclear fuel assembly (not shown). Typically, a pressurized water reactor has a number of fuel assemblies which form a core. Each fuel assembly has a flow distribution plate 3 spaced from a reactor lower support plate 4. The support plate 4 has openings 5 through which the reactor coolant flows. The flow distribution plate assists in a assuring uniform fluid flow about each fuel rod in the assembly to provide efficient cooling. The 10 shroud 1 has a cup portion 6 with a tapered end 7 and arms 8 which extend to support the shroud. Referring to FIG. 2, the cup 6 is disposed between the flow distribution plate 3 and the support plate 4. An instrument thimble tube 9 extends through an opening 10 in the support plate, passing through a hole 11 in a top surface 12 of the cup, and through an opening 13 in the flow distribution plate, into a thimble guide tube 14. The cup has a cylindrical shape and has an inner diametrical opening 15 sufficient to pass the instrument tube therethrough. Sufficient clearance is also provided to allow liquid flow around the instrument tube. For example, the cup may have an inner diametrical opening 15 of about 1.5 inches, with a clearance between the thimble tube 9 and hole 11 of about 0.071 inches. The cup isolates the thimble tube passing through the openings to prevent excessive wear due to vibratory contact with the adjacent surfaces due to the intensity of the fluid flowing through the fuel assembly. The cup allows flow through and about the instrument thimble tube 9 in a controlled fashion, using passages 16 in the tapered end 7. The arrows A illustrate the flow separation within the cup with part of the flow directed out of the passages 16 and part directed through the hole 11 into the guide tube 14. The cup isolates the instrument tube from cross flow in the spacing between the distribution plate 3 and support plate 4. Consequently, fluid flow is maintained within the guide tube 14 yet is moderated by the passages 16 to a degree which minimizes vibration and potential damage of the instrument thimble tube. Referring again to FIG. 1, cup 6 has four arms 8 which extend radially. The arms maintain the shroud in an axial orientation and prevent rotation or twisting which could cause the shroud to move and itself damage the instrument thimble tube. Each arm 8 has a locking pad 17 which engages complimentary structures in the nozzle 2. Referring to FIGS. 3, 4, and 5 a-c, each locking pad 17 has a spacing lip 18 and incorporates a spring plate 19, which is attached preferably by bolting or welding to the pad. Each spring plate 19 has a pair of spring arms 21 which have sloped surfaces 22 and 23 to ease entry and exit into the nozzle. These spring arms mate with recesses 20 in the nozzle 2, and bias the shroud into maintaining it's engagement with the recess. Referring to FIGS. 3 and 5a-5c, a separate retaining spring 25 locks the pad in it's engaged position. The retaining spring 25 has an angle surface 26 leading to an angled tab 27. As the angle surface 26 engages a shoulder 24 of the bottom nozzle 2, it causes the angled surface 26 to be deflected as the shroud is inserted in nozzle 2. Once the spring arms 21 seat in their respective recesses 20, the angle tabs 27 contact shoulders 24 and prevent the shroud from being withdrawn. Before the shroud can be removed, the retaining spring 25 must be released. FIG. 6a shows the spring 25 in a relaxed condition prior to mounting, FIG. 6b shows the springs at maximum deflection, traveling across a shoulder 24 in the nozzle 2. The shroud is preferably made of a material compatible with nuclear reactor service. For example, the shroud may be composed stainless steel, zirconium, or a zirconium alloy such as Zircaloy-2 or -4. The springs may be made of the same materials or of a nickel alloy material such as Inconel. In addition, the number and types of spring means and/or arms may vary depending on the location of the shroud within the fuel assembly. Utilizing the thimble tube shroud of the present invention, having arms and spring pads, prevents rotation or shifting of the shroud and prevents damage to the instrument thimble tube. Also, the shroud reduces and redirects flow around the instrument thimble tube without detrimentally affecting cooling or flow of the coolant about the instrument thimble tube. Consequently, the inventive shroud prevents vibration damage to the instrument thimble tube passing therethrough, enhancing life of the instrumentation and allowing continued observation of dynamics within the nuclear reactor. While preferred embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes and modifications could be made without varying from the scope of the present invention.