Patent Number: 039765431
Section: description

SPECIFIC EMBODIMENT OF THE INVENTION The assembly is a preset temperature actuated bistable device for automatically removing the restraint on a neutron absorber allowing the absorber to insert into the core of a liquid sodium cooled fast breeder nuclear reactor thus preventing core overheating due to excessive power for a given coolant flow. Referring to FIG. 1, a neutron absorber 10, hexagonal in cross section, is surrounded by a slightly larger doublewall hexagonal tube having an inner tube 12 and an outer tube 13. The annulus therebetween is filled with two rows of fuel pins 15 some of which are interrupted to allow space for circular "L" shaped flanges 14 made of stainless steel and welded to three sides of the inner tube 12 at the same elevation on the tube. The outer tube 13 has holes 19 therein within which circular flanges 14 fit tightly; a lip 14a on each flange forms a smooth continuous surface with the surrounding outer tube 13. This minimizes interference with sodium coolant flow around the outer tube 13 and allows the tubes 12 and 13 to be placed adjacent to other hexagonal tubes, not shown, in the reactor core which contain similar absorbers, control rods, or fuel rods. Each circular flange 14 contains a bimetallic disk 16 and a nickel-chromium-iron alloy helical spring 17 trapped compressively between the flange and the disk. The lip 14a is only wide enough to support the spring 17; a hole 14b defined by the lip 14a insures intimate contact between the sodium coolant and the disk 16 so that heat transfer will be improved. The hole 14b also facilitates inspection of the disk 16 and spring 17. Each bimetallic disk 16 is shaped as a spherical cap and is made of a layer 18 of molybdenum on the inside or normally convex side of the disk and a layer 20 of stainless steel on the outside or normally concave side of the disk. This relationship of concave and convex sides will hereinafter be described as the closed position of the disk 16. These materials are chosen for the difference in their thermal coefficients of expansion which gives the switching action as well as for their compatibility with high temperature liquid sodium coolant and a low tendency to interdiffuse at high temperatures; other suitable material combinations, such as a nickel-chromium-alloy on the outside with molybdenum or a molybdenum-titanium alloy on the inside are also suitable. As shown in FIG. 2, the inside or normally convex side of the disk 16 has a spherical depression 22 formed in it; its radius is slightly larger than the radius of a metal ball 24 made of cobalt alloy tool material whereby a smooth sliding fit is obtained between the depression 22 and the ball 24. The ball 24 is rotatably retained in the depression 22 by a retainer 26 formed as part of the material of the inside layer 18. The cross section of the retainer 26 is substantially right triangular where one right triangular leg is integral with the inside layer 18 and the other right triangular leg is curved slightly to match the radius of the depression 22 whereby the ball 24 is rotatably retained. In the embodiment shown, the depression 22 is large enough so that it penetrates completely through the inside layer 18 of the disk 16, thus defining a hole 23 in the inside layer 18 with the shape of a zone of a sphere, and a spherical depression 25 in the outside layer 20. However, this is not critical; depending upon the size of the ball 24 in relation to the disk 16, the spherical depression 22 may or may not penetrate through the inside layer 18 and into the outside layer 20. The ball 24 is thus trapped in the disk 16 and faces a port 28 in the side of the inner tube 12 which is located concentrically with a line normal to the plane of the side and passing through the center of the ball 24. The disk 16 is urged toward the inner tube 12 by the spring 17. The ball 24 is large enough to project partially through the port 28 in the closed position to the inside of the hexagonal tube 12 as shown in FIG. 1. The absorber 10 is supported solely by means of the conical bottom 30 thereof resting upon the metal ball or balls 24. As shown in FIG. 4, a thin layer or foil of fissionable metal 34 may be disposed in the bimetallic disk 16. Fissions at a rate proportional to reactor power will then take place in the disk 16, thus generating heat within the disk itself to raise the temperature of the disk in addition to relying on heat addition from core components or coolant. If desired, the fissionable material may be in the form of a metal oxide 36, dispersed as nodules in at least one of the layers 18 and 20 of the disk 16 as depicted in FIG. 5. The addition of fissionable material in either form is not necessary to the invention, but can be used to decrease the response time of the disk 16 in the event of a dangerous power increase. The exact distribution and quantity of material used depend on other core parameters, such as type of coolant, location of the assemblies in the core, neutron spatial and energy distributions, reactor power, etc. Referring to FIG. 3, upon reaching a preset temperature in the range of about 550.degree.C. to 770.degree.C. (the exact temperature being determined by the difference in thermal expansion coefficients and diameters and thicknesses of the two metals in the bimetallic disk 16), the difference in thermal expansion coefficients gives rise to imbalanced thermal stresses, which cause at least one disk 16 to switch so that the inside layer 18 is now concave and the outside layer 20 is now convex. Thus concave and convex sides will now be reversed. This position of the disk 16 will be referred to hereinafter as the open position. The disk 16 does not bend or retract gradually from the closed to the open position or vice versa. The generally spherical shape of the disk 16 gives it a bistable characteristic, that is, it has two stable states; all other states are unstable. When the preset temperature is attained by heating the disk 16, the disk will, if in the closed position, snap abruptly to the open position. Conversely, if the preset temperature is attained by cooling the disk 16, the disk will, if in the open position, snap abruptly to the closed position. For this reason, bimetallic disks are used, for instance, as contacts in electrical switches. The lateral displacement is sufficient to pull the ball 24 from the inside of the inner tube 12. The conical bottom 30 of the absorber 10 also exerts a force which tends to push the ball 24 out of the tube 12. The absorber 10 is sufficiently smaller than the tube 12 so that removal of any one ball 24 will allow the absorber 10 to slip off the remaining two balls 24 and be inserted into the nuclear reactor core. When the absorber 10 has been fully inserted into the core, it will be below the disks 16 as shown by FIG. 3. When the actual temperature is again below the preset temperature, any open disk 16 will switch to the closed position due to the imbalanced thermal stresses, which tend to produce an opposite effect when the actual temperature falls below the preset temperature. Hence, the spring 17 is required so that when the absorber 10 is lifted into position for another use, as shown in FIG. 1, a top chamfered edge 32 on the top of the absorber 10 will gradually push the disks 16 back against the springs 17 until the absorber 10 has been lifted above the disks, when the spring will push the closed disks 16 back into position so that the absorber 10 may be rested on the balls 24.