Patent Number: 047145820
Section: description

DETAILED DESCRIPTION OF THE INVENTION Referring to FIGS. 1 and 2, an actuating device for moving a cluster constitutes part of the mechanism for controlling a set of two clusters of vertically movable control elements and engaging them more or less deeply in a same fuel assembly of a reactor. Hereafter, that one of the two clusters which is moved by the device will be called "lower cluster" and the other "upper cluster". However, under certain operating conditions, the so-called upper cluster may be situated below the other. The upper cluster (not shown) may typically comprise elongated elements or rods containing a neutron poison and be used for adjusting the power of the reactor. The upper cluster is carried by a tubular drive shaft 10 slidably received in a tube (not shown) projecting through the cover of the reactor vessel. Shaft 10 is controlled by drive means which may have a number of different constructions. The drive means may for example be one of those described in French Pat. Nos. 2,537,764, 2,232,820, 2,106,373 to which reference may be made. The lower cluster is arranged for connection to and disconnection from a drive shaft 12, coaxial with shaft 10. As shown in FIG. 2, the lower cluster comprises four sub-clusters 14 (this number not being limitative) of sixteen elements each. Each of the sub-clusters 14 cooperates with associated gripping means formed by a nipper or gripper 16 fixed to an arm of a cross piece 18 fixed to the shaft 12 (FIGS. 1 and 2). The nature of the elongated elements forming the sub-clusters will depend on the contemplated use. The elements may contain a high proportion of neutron absorbing material, when the lower cluster is shutting down the reactor. The cluster may also comprise moderating or neutron-transparent material, when it is desired for example to modify the moderation ratio of the reactor during the life of this latter. They may contain fertile material in place of or in addition to other materials. The drive shaft 12 has at its lower part a resilient shock damper 20, which comes into contact with the upper core plate 22 during downward movement of shaft 12 supporting the clusters and which slows down the end travel in case of free fall of the shaft. Each set of two clusters associated with a fuel assembly, such as the assembly whose upper end piece or nozzle 24 is shown in FIG. 1, is associated with stationary retaining and guide means belonging to the internals of the reactor. The guide means comprise a guide tube 26 fixed to the upper core plate of the reactor (which is part of the upper internals of the reactor) and having an upper structure 28 in which are formed housings 30 each for receiving a grab 32. In the embodiment as described, the upper core plate forms a lower structure supporting the cross piece 18 and the sub-clusters 14 when they are in their lower position. The actuating device comprises a grab 32 for each sub-cluster 14. Each grab may have the construction as shown in FIGS. 3 to 6. The elongated elements of the sub-clusters are suspended from radial arms of the tubular body 34 of the grab. The top part of the tubular body 34 is split up, by slits 37 parallel to the axis and spaced apart at regular intervals, into flexible fingers 38. Each flexible finger has two projections 40 and 42 separated by an intermediate groove 44. The lower part of the body 34 slidably receives a stop member 36 carried by a pin 46 limiting downward movement of the stop away from a transverse partition 48 of the body. A return spring 50 urges stop 36 towards the lower position in which it is shown in FIGS. 1 and 3. Spring 50 is thus retained under a prestress, so calibrated that the spring contracts and allows stop 36 to move with respect to body 34 only when subjected to a force greater than the weight of the sub-cluster and to the snap engagement force of the body 34 of the sub-cluster 32 in housing 30. The housing 30 for receiving each grab in the upper structure 28 has a rotational symmetry. It comprises, from bottom to top, an entrance chamfer 52, an internal flange 54, a recess or counterbore 56 and a shoulder 58 connecting with a portion 60 of a smaller diameter than that of flange 54. Grooves 62, four in number as illustrated, divide up flange 54 at regular angle intervals. Their depth is such that their bottom is in alignment with that of the recess 56 and their function will be discussed further on. The axial dimension of recess 56 is such that it may receive both projections 40 and 42 together, as shown in FIG. 3. Each of the nippers 16, carried by arms of the cross piece 18, comprises four rigid blades 64 whose dimensions and mutual spacing are such that they may engage grooves 62 of housing 30 during upward movement of the nipper. Each of blades 64 ends with a latching lip 66 arranged for passing between the arms of the grab 32 and for: abutment with the projection 42, for supporting the grab 32, insertion into the intermediate groove 44 of the grab so as to connect the nipper 16 to grab 32, when the nipper is raised into the grab while the grab is in its upper abutment condition. The bottom wall of nipper 16 is formed with several holes 68 distributed about the vertical axis of the nipper, opposite the tubular body 34 of the grab. Holes 68 are located for providing a passage for fingers 70 arranged for forcibly disengaging the nipper. In the embodiment shown in FIG. 6, fingers 70 are carried by the end nozzle 24 of the fuel assembly which forms the lower fixed structure of the device. However, other arrangements are possible. Fingers 70 have a sufficient length for retaining the body 34 of grab 32 against axial movement when the latter is pulled downwardly by nipper 16 engaged with fingers 38. The operation of the device during the different possible phases is as follows. Locking of the grab in top position First, the upper cluster should be moved to its top "over travel" position, i.e. to a position which is above the top position in which it will later be retained. Locking of the grab in the top position automatically occurs by snap action upon upwardly moving the nipper 16 on which the grab simply rests (FIG. 1). The projections 40 of fingers 38 first engage the entrance chamfer 52. Upon continued upward movement of the nipper 16, the force transmitted from the nipper to the grab through stop 36 and spring 50 is sufficient for bending fingers 38 inwardly while projections 40 slide over the chamfer. As soon as projections 40 and 42 confront the recess 56, the fingers revert to their original shape and the projections snap into position and lock the grab. Upward movement of nipper 16 is then stopped. Cross piece 18 may then be moved down (FIG. 3) to its lower position, thus completely freeing the path of the other cluster. Grabs 32 and the sub-clusters 14 remain in their top position. Unlocking and lowering In order to bring the cluster to the low position, the cross piece 18 is raised. Lips 66 engage projection 42 and the bottom wall of nipper 16 comes into abutment against stop 36. Upon further upward movement of nipper 16, spring 50 is compressed and simultaneously fingers 38 are forced radially inwardly by the rigid blades 64 guided by recess 56 and grooves 62. Lips 66 snap into groove 44 whose depth is such that the projections 40, still in abutment against shoulder 58, have a size less than the passage area left free by flange 54 (FIG. 4). If then shaft 12 and cross piece 18 are lowered, they then carry the grab 32 engaged with nippers 16 and the sub-clusters 14 (Figure 5). The cross piece may thus be lowered as far as the lower position defined by abutment of the tubular body 34 of grab 32 on pins 70. Disconnection and raising When it is desired to move the sub-clusters 14 back to their top position, grabs 32 are first of all disengaged from nippers 16. Disconnection is effected by moving shaft 12 down by an additional extent. The body 34 of grab 32 is then retained by the fixed pins 70 and lips 66 escape downwardly, while temporarily bending the resilient fingers 38. As soon as the lips have left grooves 34, spring 50 raises the grab which comes into the position shown in FIG. 6, bearing on lips 66 and through stop 36, on the bottom of the nipper. Stop 36, arranged to rest on the bottom wall of nipper 16, fulfils two functions: When the grab is engaged with the nipper (FIG. 5) the stop holds the grab in a well defined position with respect to the nipper, since the compression force of the spring is less than the resilient locking force. The stop takes up possible lost motion and avoids shocks and fatigue effects. The resilient stop in addition relieves pins 70 when two-way connection changes to a simple bearing contact. In fact, spring 50 whose precompression force is greater than the weight of the sub-cluster, assists pins 70 in their action. It will be appreciated that the device moves the sub-clusters into their upper connection position. They may leave them and bring them back to the lower position, so making the sub-clusters completely independent of the movement of an additional cluster consisting of neutron absorbing control elements. It is important to note that the whole of the engaging and disengaging, locking and unlocking operations is controlled solely by movements of the nipper, without any auxiliary member. The control mechanisms may therefore be very simple and may be of existing types which provide a largely sufficient positioning accuracy for blindly effecting the different operations required.