Patent Number: 039309380
Section: description

DESCRIPTION OF THE PREFERRED EMBODIMENTS The fuel assembly 1 shown in FIG. 1 has within a cover a number of fuel rods 2 which are attached to end plates 3 and 4. Two control rods 5 are positioned inside the assembly among the fuel rods. The control rods are made in the form of "fingers" and are therefore called finger control rods. The control rods are attached at their lower ends to a yoke 6 which is shown more clearly in FIGS. 4 and 7. The attachment is made by using any known method capable of being released by turning the rod, for example bayonet joint, spring lock, threading, or the like. In the figure the use of bayonet joint is shown. The control rod is displaceable in a guide tube 7 which is attached in the fuel assembly. Between the control rod and the guide tube there is a gap for the water flowing from below, and the gap has such a width that the rod maintains a suitable temperature. In order to make sure that the control rod is not turned and unintentionally affected so that it gets detached from the fastening device, it is provided at its upper end with a locking device which is shown in a larger scale in FIGS. 1A and B and FIGS. 2 and 3. The control rod 5 has at its upper end an extension constituted by a pin 25 threaded at 26 in a bore 27 in the top of the control rod. The pin 25 terminates at its upper end in a conical top 28 and below this is a cylindrical part 29. Pin 25 and the bottom part of the cylindrical part 29 are surrounded by a sleeve 8. The cylindrical part 29 is provided with two axial grooves 30 and two lugs 31 at the upper end of the sleeve 8 are situated in the grooves. The grooves 30 and lugs 31 allow the sleeve 8 to move axially on the pin, but prevent it from rotating thereon. The cylindrical part 29 has a greater diameter than the rest on the pin 25, and the bottom surface of part 29 outside the lower part of pin 25 forms a stop surface for a washer 33 for the upper end of a spring 10, which is situated inside the sleeve 8 and surrounding pin 25. The bottom end of spring 10 abuts a stop-surface 32 inside the sleeve 8. Thereby sleeve 8 is restrictedly displaceable in the axial direction along pin 25 at the top of rod 5, but is non-rotatably arranged on pin 25 and is pressed downwards against the top surface 34 of the fuel rod 5 by the spring 10. When the control rod is in its topmost position (as shown in FIG. 1), the locking sleeve 8 is at the upper end of the guide tube 7. From FIG. 2, which shows a cross-section of the control rod along the line II--II in FIG. 1, it is seen that a locking ring 11, having the same contour as the guide tube 7, is situated inside the guide tube and fastened to the locking sleeve 8 by means of bars 34 secured to the tube 8 and ring 11. There is a narrow slot 35 between the guide tube 7 and the locking ring 11, and the sleeve 8 can move up and down inside the guide tube 7. The cooling water passing upwardly in the space between the rod 5 and the tube 7 can pass through the spaces 36 between the bars 34. As long as the locking ring 11 for the tube 8 is inside the guide tube 7, the control rod is locked against turning but displaceable upwards and downwards under the influence of the reactor control drive for the control rods. This control drive is already well-known and therefore is not shown. When the control rod is to be removed, the control tube 8 is lifted against the action of the spring 10, for example by a gripping member which engages in recess 36 in the sleeve 8, so high that the locking ring 11 is located above the upper end of the guide tube. After this, the control rod is turned so that the bayonet holder releases its hold and the rod can be pulled up. If circular guide tubes are used, as shown in FIG. 3, the guide tubes can be provided with a pair of longitudinal internal ribs 12. The tube 8' is then provided with a number of corresponding projections 13 which prevent the tube from turning as long as the projections 13 are within the guide tube. In the same way as described in connection with FIG. 2, the control rod 5 and the locking tube 8' are released for turning as soon as the tube has been lifted up so high that the projections 13 are free of the ribs 12. The two embodiments now shown have the advantage that the assembly can be removed even if it should be impossible, for some reason, to operate the locking means. Then the rod can be turned and removed without its being necessary to displace the tube 8. FIGS. 4 and 5 show schematically how four control rods 5 in a fuel assembly are attached to a yoke 6, this being operated upward and downward by a control drive not shown. The yoke is provided with a hub 14 in which the drive bar 15 is attached. From the hub 14 four arms 16 extend, said arms supporting at their outer ends fastening plates 17 for the fastening devices of the control rods, said fastening devices being shown here as bayonet joints comprising a slot 18 in the fastening plate and corresponding cam projections 19 on the control rod. The design of the locking device as a bayonet joint is shown only to exemplify the idea of the invention, and other previously known locking devices, threaded screws, spring lock and the like could be used. FIGS. 6 and 7 shows how four adjacent fuel assemblies 1 are brought together to form a group and arranged in such a way that their control rods are adjustable simultaneously with the help of one single drive bar 20 which is connected to a group yoke 21 common for the whole group, as shown in FIG. 7. The group yoke has four arms 22, each arm supporting an assembly yoke 23 of the type shown in FIG. 5. In order to make possible change or inspection of individual assemblies within the group, the assembly yoke 23 should be detachably attached to the group yoke. This attachment could be constructed by providing an operating rod 24, which is positioned in the center of each assembly, its lower end with a fastening device of, for example, the kind mentioned previously and giving the operating rod such a length that it reaches and preferably lies above the upper surface of the fuel assembly when the control rods are in their upper position and, therefore, easily accessible from above. Also this operating rod should be provided with a locking device, so that the assembly yoke cannot be detached unintentionally from the group yoke. The operating rod could consist of an ordinary finger control rod or be constructed of a material with the least possible neutron absorption, in the event it is not to affect the course of the reactor. In the latter case, the operating rod can be made so as to be removed from the fastening device after the desired operation has been carried out. In an embodiment of the invention as shown in FIGS. 6 and 7, the whole assembly yoke 23 is lifted together with the assembly when the assembly is removed from the reactor. The control rods can therefore be attached to the yoke by means of, for example, welding or any other suitable attachment method. Instead of the locking device shown in FIGS. 1, 2, and 3, locking of control rods and operating rods can be accomplished with the help of springs actuating, for example, square parts of the rods. When the locking device is to be made inactive, the rod is turned against the action of the springs so that the springs come to lie above the diagonal on the square part. In this position, the fastening device is open so that the rod can be removed. Locking devices of this kind are so well-known that they need no further explanation.