Patent Number: 039649679
Section: description

DETAILED DESCRIPTION FIG. 1 shows a typical fuel element for nuclear reactors involving this invention. It comprises a fuel tube 2 preferably made of a substantially non-magnetic structural material, such as type 316 stainless steel, zircaloy-2 or zircaloy-4. It is closed at the lower end by a bottom end cap 4 which is welded in place. Within the tube is a stack of fuel pellets 6, made of uranium dioxide enriched in uranium-235, or a mixture of uranium dioxide and plutonium dioxide. Between the fuel and the lower end cap are lower insulator pellets 3, formed of aluminum oxide or uranium dioxide depleted of uranium-235. A neutron reflector 10 made of a high nickel alloy may also be provided. The upper end of fuel tube 2 is closed by upper end cap 12. The column formed by the fuel pellets 6, upper insulator pellets 14 and upper reflector 16 is spaced from the upper end cap 12 to form a plenum filled with helium. The spacing is produced by a plenum spring 18, a hollow cylindrical plenum spacer 20 and the tag gas capsule 22. The tag gas capsule 22 is shown in more detail in FIGS. 2 and 3. It includes a cylindrical casing 24 closed at one end by bottom plug 26 and at the other by a rupture cup 28, which includes a thin diaphragm 29 which is, e.g. about 0.004 inch thick. It is preferably made of annealed 316 stainless steel. The capsule is preferably positioned with the rupture cup at the upper end so that end cap 12 will act as an anvil. The rupture cup serves to space diaphragm 29 from the end cap to permit penetration by punch 30. Bottom plug 26 is relatively thick, e.g., 0.020 inch. A punch 30 is slidably housed within capsule 22. The punch has a body portion 32 and at least one sharp pointed penetration portion 34. Preferably the punch is made double-ended so that it cannot be inserted incorrectly. The penetrating portion may be integral with the body portion or it may be separate, but suitably secured to the body portion. The body portion, at least, of the punch is made of a metal which is strongly ferromagnetic, for example, type 410 stainless steel. The casing 24, on the other hand, is made of a material which is nonmagnetic or at least only weakly magnetic, e.g., zircaloy-2 or type 310 cold worked stainless steel, to minimize magnetic shielding of the punch. The actual loading of the capsule with a tag gas may be carried out in conventional equipment. The bottom plug 26 may, for example, be drilled by a laser beam, to provide a small hole 36. The capsule is then evacuated and backfilled with the desired mixture of isotopes such as xenon - krypton gas mixtures. The hole 36 is then closed, e.g., by laser welding. It should be apparent that multiple capsules may be loaded by this technique simultaneously and due to the cost savings, multiple loading is preferred. OPERATION The operation whereby the tag gas is released from the sealed capsule 22 into the fuel element is shown diagrammatically in FIGS. 2 and 3. A support block 54 is provided with a guide groove. The support block may be positioned horizontally on a suitable table or work bench. Intermediate in lengths are one or more permanent magnets 58 which are mounted adjacent the guide groove. Electric coil 60 which is mounted at one end of support block 54 has a bore 62 aligned with the guide groove. At its terminal end coil 60 has a microswitch 64, which is connected to coil 60 through a circuit which delivers a short but heavy pulse of current. After the capsule 22 has been placed in the fuel tube and upper end cap 12 welded in place, the fuel element is placed in the groove of block 54 with end cap 12 to the right of magnets 58 in FIG. 2. The fuel element is then slid along the groove past magnets 58 which move punch 30 to the bottom of the capsule 22, adjacent bottom plug 26 as shown in FIG. 2. This is termed the "cocked" position of the punch. When the end plug 12 contacts microswitch 64 a strong pulse of current is sent through coil 60. This drives punch 30 toward rupture cup 28. The current is cut off when punch 30 reaches the midpoint of coil 60. The punch 30 strikes and penetrates diaphragm 29 of rupture cup 28, as shown in FIG. 3. The gas escapes into the remainder of the fuel element. The stainless steel diaphragm 29 tears irregularly, releasing punch 30, which drops back as soon as the fuel element is placed upright. To ensure that the punch has penetrated the diaphragm, the piercing operation may be repeated. This is done by drawing the fuel rod to the right in FIG. 2 until end cap 12 has cleared magnets 28, then sliding it to the left again cocking the punch and then driving it against the diaphragm a second time. While I have shown and described the presently preferred embodiment of the invention, various changes can be made. For example, the punch might be placed outside the capsule, e.g., in plenum spacer 20. In this modification, the diaphragm 29 would of course be at the bottom of capsule 29. I therefore wish the invention to be limited solely by the scope of the appended claims.