Patent Number: 039322157
Section: description

Referring now to the drawing and first, particularly, to FIG. 1 thereof, there is shown therein an absorber 1 formed of three members that is guided in a guide tube 2 which, at its lower end, is held in a sleeve 3 that is secured to the grid support plate 4. During operation of the reactor, the lower end of the absorber 1 rests in a correspondingly shaped end section 5 of the guide tube 2, sealing it, and thereby largely prevents coolant from entering the guide tube 2. The guide tube 2 is held at its upper end in a centering tube 6. The absorber 1 is connected through a connecting device 7, which need not be described in detail as it is not essential to the invention, to one end of a tie rod 8. The other end of the tie rod 8 is secured to the lower part of a bayonet coupling 9 of conventional construction. The latter, in turn, is connected with the upper part thereof to a connecting rod 10. When the connecting rod 10 is turned, it causes disengagement of the bayonet coupling 9, whereupon the entire device can be pulled up and only the parts 1 to 5, 7 and 8 of the control rod remain in the reactor in the shut-off position of the control rod. In FIG. 2, the reduced-diameter centering tube 6 and guide bearing 11 form a dashpot 12 in which the connecting rod 10 displaces a damper piston 13 that is mounted thereon, thereby braking the motion of the absorber mechanism, when it is moved rapidly upwardly to the shut-off position shown, prior to reaching that final shut-off position. The centering tube 6 is mounted in a tube 14. Shielding 16 is disposed in the space between the inner surface of the tube 14 and the outer surface of a tube 15 disposed within and coaxially to the tube 14. The tube 15, in turn, surrounds a guide tube 17. In FIG. 3, the tube 14 is seated with a shoulder thereof on the lid of the reactor. A cover 18 seated on the tube 15 closes off the shield 16 at the top thereof. A sleeve 20 connected to the tube 17 and provided with an external thread and a conical seal 19, is disposed on the cover 18. Upon rotating a tube 23 in which a nut 21 is disposed, the sleeve 20 is screwed into the nut 21 until a conical seal 19 comes to rest against a correspondingly shaped interior cone 22, so that gas is prevented from escaping from the reactor by a seal 53. At the same time, the centering tube 6 is lifted through the tube 17 for such a distance that a gap is formed at the junction between the centering tube 6 and the guide tube 2 (note FIG. 1), and it is thereby possible to rotate the reactor lid to carry out fuel element replacement operations. The tube 23 is connected through a gear coupling 24 with a sleeve 25 which, at the upper end thereof, is provided with a gear 26 that meshes with a pinion 27 mounted on a universal joint drive shaft 28. The gear coupling 24 is required so that, when a chuck 29 of conventional construction, is disengaged, the tube 23 can be separated from the housing 30 that is slid over it. The universal-joint shaft 28 with its pinion 27 are supported in the housing 30, as well as a universal-joint shaft 31 with a pinion 32 secured thereto, which engages a gear 33 mounted on a shaft 34 that is connected to the rod 10 through the chuck 29. When the chuck 29 is disengaged, the parts of the device which have been in contact with the coolant can be separated from the other parts. The chuck 29 also facilitates the installation or assembly of the device. The housing 30 is connected to a tube 36 through an intermediate section 35. FIG. 4 shows the tube 36, in which a holding plate 37 is secured. A helical spring 38 bears against the holding plate 37. If a lead screw 39 is turned, the rotation thereof is transformed into axial motion by a nut 40, and a disc 41, which is rigidly connected to the nut 40 and is prevented from turning by a retaining slot 42 on the inside of a tube 43, slides downwardly. On the disc 41, there is secured a toroidal electromagnet 44, the leads of which are not illustrated. In the energized condition, the electromagnet 44 entrains an armature 45 resting against it, which slides along retaining slots 46 formed on the inside of the tube 36. The helical spring 38 is thereby stressed and the tube 43, which is firmly connected to the armature 45, slides farther downwardly and thereby lowers the shaft 34 suspended in a holder 47, the shaft 34 being drawn downwardly by the gravity force of the absorber 1, which is connected to it by the parts 29, 10, 9, 8 and 7. A stop 48 limits the travel of the armature 45 upwardly during shut-off. A gas seal 49 prevents radioactively contaminated gases from escaping from the reactor. The lead screw 39 is turned by an electric motor 52 which operates through a reduction gear 50 and an overload clutch 51, of conventional construction and therefore not further described in detail. The overload clutch 51 prevents the drive mechanism from being damaged in the event of jamming of the linkage. The universal-joint shafts 28 and 31 are constructed at the upper end thereof so that they can be rotated, for example, by means of a wrench. The upper part of the entire device is secured in a holder plate 54. The traction device forms one unit during normal operation, but in the event of the reactor cover having to be rotated or lifted off for maintenance work, is divisible into a lower part (connecting device 7, tie rod 8 lower half of bayonet coupling 9) and an upper part (upper half of bayonet coupling 9, connecting rod 10, chuck 29, shaft 34, holder 47, tube 43 and armature 45). The parts linking the absorber to the spring 38 which are set in motion when rapid shut-off is triggered include connection device 7, tie rod 8, bayonet coupling 9, connecting rod 10, chuck 29, shaft 34 holder 47, tube 43 and armature 45. Referring to FIG. 5, the bayonet coupling 9 comprises an upper part 55 and a lower part 56 detachably connected to each other by means of a gear coupling which is also shown in FIG. 6. The rod 10 is provided with segments 58 which can engage appropriately shaped recesses 59 of the lower coupling part 56. FIG. 6 shows the coupling in disengaged condition whereby the rod 10 and thus segments 58 and the upper part 55 of the coupling can be pulled away in an upward direction. When the rod 10 is rotated 90 degrees, segments 58 engage the recesses 59 and lock the coupling parts 55 and 56 with respect to each other, and their mutual gearing prevents the rotary movement of the rod 10 from being transmitted to the lower coupling part 56 and to the remaining parts 1, 7, 8 of the device suspended thereon. A Part 60 is provided at its upper end with an internal hexagon opening for accomodating a hexagon part 57 so that the rotary movement of the rod 10 can be transmitted to the part 60. The part 60 is provided with two flanges 61, 62 which, in the illustrated embodiment, each comprise three control slots 63 as shown in FIG. 7. Inside the control slots, are disposed glide pins 64, which have latches 65 attached thereto and which, at an appropriate position of the pins 64 in the control slots 63, as shown in FIG. 7 for example, engage the openings 66 in the guide tube 2. The operation of this latch system and the bayonet coupling 9 is coupled that upon rotation of the rod 10 for releasing the coupling parts 55 and 56 from each other, segments 58 emerge from recesses 59 thereby releasing the coupling and this same rotation shifts, simultaneously, part 60 and thereby the guide slots 63 in such a manner that the latches 65 engage the opening 66. As a result, coupling parts 55 and 56 which are geared with each other, as well as the hexagon part 57 and part 60 are released from one another, through a simple pulling upwardly of the rod 10 while the absorber 1 remains securely locked in its disconnected position. The high temperatures prevailing in the fission zone of the reactor, the radiation stress, and possible interferences make the pull rod 8 particularly susceptible to danger of being damaged. To insure that, in any event, the absorber 1 will be pulled into the core region, the upper and lower end parts of the pull rod 8 (FIG. 5 shows only the upper end part 67) are so arranged that a wire rope 69, whose ends are provided with ballshaped holders 68, can be guided in the interior of the hollow pull rod 8 as a reserve pulling member. FIG. 8 shows how the individual parts of the absorber 1 are connected by means of joints which consist of meshing extension sections or bulges 70 and 71 which are disposed at various locations. The individual parts of the absorber 1 are limited by stops, 72, 73 and can be shifted relative to each other, to a certain degree and especially, may be tilted, canted, and twisted oppositely relative to each other so that absorber 1 can also follow through guide tube 2 which becomes curved due to a disruption or the like. The operation of the device is as follows: When rapid shut-off is triggered, the electromagnet 44 ceases to carry current and releases the armature 45 which is forced upwardly by the stressed helical spring 38 to the stop 48 and thereby entrains the tube 43. The shaft 34 suspended in the mounting 47 is also forcibly pulled upwardly and, in turn, pulls up the chuck 29, the rod 10, the bayonet coupling 9, the tie rod 8 and the fastening device 7 and thereby draws the absorber 1 into the reactor core region. Simultaneously, the electric motor 52 is started up and pulls up the disc 41 through the reduction gear 50, the overload clutch 51 and the lead screw 39 and thereby forcibly entrains the armature 45, in case the latter should not have been impelled to its upper rest position. After correcting the reactor trouble which caused the aforedescribed rapid shut-off, the operational readiness of the device is restored as follows: The electric motor 52 is driven in the opposite rotary direction, and through the lead screw 39, causes a lowering or unscrewing of the nut 40, and the disc 41 and the electromagnet 44, which is simultaneously energized and thereby entrains the armature 45 downwardly against the biasing force of the helical spring 38. The tube 43 and the holder 47 connected thereto, are thereby moved downwardly, so that, due to the force of gravity, the absorber 1 which is suspended on it by means of the parts 34, 29, 10, 9, 8 and 7 slides downwardly out of the reactor core region, until the lowermost member of the absorber 1 rests in the end section 5 of the guide tube 2, thereby terminating the shut-off of the reactor. To disengage the bayonet coupling 9, the universal joint shaft 31 is rotated, imparting its rotation through the pinion 32 to the gear 33, and through the latter to the shaft 34 which, in turn, sets the connecting rod 10 in rotation through the chuck 29, and thereby initiates the coupling operation. The rotation of the universal-joint shaft 28, through the pinion 27 and the gear 26, causes rotation of the sleeve 25 which, through the gear coupling 24, turns the tube 23 and the nut 21 in which the sleeve 20 is screwed and which is fastened in the tube 23. The tube 17 connected to the sleeve 20 rises and entrains the centering tube 6, whereby the latter's connection to the guide tube 2 is released and a gap between these two tubes 6 and 17 is formed. After disengagement of the bayonet coupling 9, the reactor lid, with the parts of the device built into the same, is then rotatable, while the parts 1 to 5, 7 and 8 remain fixed in the reactor.