Patent Number: 042082498
Section: description

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS For a more complete appreciation of the invention, attention is invited to FIG. 1 which shows a fuel assembly 10. Comprising the fuel assembly 10 is a group of long, slender fuel rods 11, the lengthwise axes of which are arranged in a generally parallel array. One end of the fuel rods is received in an end fitting 12. As illustrated, the end fitting 12 has a cellular grill 13 that is disposed in a direction which is transverse to the lengthwise axes of the fuel rods 11 in order to engage the ends of these rods, thereby to bear the movement of the fuel rods in a lengthwise direction. The end fitting 12 further includes a monolithic end casting 14 that supports the cellular grill 13. As shown, the end casting 14 is generally in the shape of a hollow cube, open at its transverse ends and provided in each of the respective cube faces with lengthwise slots 15, 16, 17 and 20. The slots 15, 16, 17 and 20 are parallel with the lengthwise axes of the fuel rods 11. These slots, moreover, penetrate each of the cube faces for about two thirds of the lengthwise depth of the middle portion of these faces, as measured from the transverse end of the casting 14 that is spaced in the lengthwise direction from the grill 13. Stops 21, 22, 23 and 24 that have the general appearance of rivets are secured in the slots 15, 16, 17 and 20, respectively, at about one quarter of the slot depth, again measured from the transverse end of the casting 14 that is spaced in a lengthwise direction from the grill 13. Spring pads 25, 26, 27 and 30, which will be described subsequently in more complete detail, protrude from the hollow interior of the end casting 14, through the respective slots 15, 16, 17 and 20 in order to enjoy a degree of travel in the lengthwise direction of the fuel rods 11 that is limited by the respective stops 21, 22, 23 and 24 and those portions of the end casting 14 that are adjacent to the cellular grill 13 and immediately below the slots. The entire fuel assembly 10 is aligned within the reactor core (not shown in the drawing) and braced to attenuate movement in the lengthwise direction of the fuel rods 11 by means of four internal pads, of which only pads 31, 32 are shown in FIG. 1. The pads 31, 32 are secured to and depend from a transversely disposed grid (also not shown in the drawing) that spans the area above the entire reactor core. The internal pads are generally rectangularly arranged in sets of four. Each of these sets are specific to a particular one of the fuel assemblies. The internal pads, of which the pads 31, 32 are illustrative, bear against those portions of the spring pads 25, 26, 27 and 30 that protrude through the respective slots 15, 16, 17 and 20 in the faces of the end casting 14. Turning now to FIG. 2, the end casting 14 is provided with a transverse shoulder 33 that catches an edge of a portion of the cellular grill 13. As shown, the slot 15 is blocked by means of the stop 21. The portion of the spring pad 25 that protrudes through the slot 15 bears against internal pad 34 which is fixed to the grid (not shown in the drawing). In accordance with a feature of the invention, the spring pad 25 is provided with an aperture 35. A hollow guide post 36 is received in the aperture 35 for relative movement in a lengthwise direction. A pin 37 also secures a cylindrical plunger 40 to the spring pad 25. The pin 37, moreover, secures the plunger 40 in the end of the guide post 36 in order to block the otherwise open end of the post 36. The fit between the cylindrical wall of the plunger 40 and the inner wall of the guide post 36 is sufficiently loose to permit the plunger to move freely in a lengthwise direction relative to the post but nevertheless provide a reasonably fluid-tight fit between the plunger and the wall. As illustrated, the guide post 36 is oriented with its longitudinal axis parallel with the lengthwise axes of the fuel rods 11. Guide post slots 41, 42 also are formed in the walls of the post in a longitudinal direction. The widths of these guide post slots 41, 42 are adequate to enable the pin 37 to move in a longitudinal direction relative to the guide post 36 during lengthwise movement of the post relative to the plunger 40 as described subsequent in more complete detail. The depths of these guide post slots 41, 42 moreover, are equal to about half the length of the guide post 36, the ends of the guide post slots occurring above the transverse surface of the cellular grill 13. Illustratively, the guide post 36 protrudes into and is secured to the cellular structure of the grill 13. As shown, portions 43 of the grill 13 are cut away to form recesses that accommodate the depth of the guide post 36 penetration into the grill 13. A disk-shaped plate 44 is secured within the guide post 36 to the transverse surface of the cellular grill 13. The diameter of the plate 44 is gauged to plug the end of the guide post 36 in which it is lodged. An orifice 45 is formed within the plate 44 to provide a means for fluid communication between guide post volume 46 that is formed between the plunger 40 and the plate 44 and the balance of the reactor core volume. In operation, and, as shown in FIG. 3 by means of a companion structure within the end fitting 12 to that which was described in connection with FIG. 2, as the reactor core sustains a major seismic or other shock, a lengthwise component of this force compels the fuel assembly 10 to move toward the internal pad 32. The pad 32 bears against the portion of the spring pad 30 that protrudes from the end casting 14 through the slot 20. Not only is this movement of the fuel assembly 10 retarded through the resilient properties of coil spring 47, but also through the hydraulic forces that are generated within a guide post 50. Thus, the pressurized water coolant in the reactor core that fills guide post volume 51 acts as a shock absorber, the water dissipating the imposed force as it flows out of the volume 51 by way of an orifice 52 in plate 53. One of the salient features of the invention, however, is the progressively decreasing discharge area that is provided by means of the relative lengthwise travel of a plunger 54 past the guide post slots, only guide post slot 55 being shown in FIG. 3. Thus, as the shock is applied initially to the reactor core, flow of water from the volume 51 is relatively unrestricted and the lengthwise motion retarding effect of the plunger and guide post combination is relatively slight. This initially slight retardation protects reactor core components from damage that otherwise would result from the abrupt application of major force to a rigid system. As the fuel assembly 10 moves in a lengthwise direction toward the internal pad 32, the plunger 54 progressively blocks the orifice provided by the guide post slot 55 and its companion slot in the guide post 50 that is out of the plane of FIG. 3. This progressive decrease in orifice area has the effect of increasing the impedance of flow from the volume 51 into the balance of the reactor core, thereby providing for a progressive attenuation of the applied force in a manner that gradually--rather than abruptly--absorbs this force. The progressive attenuation of the force in question that characterizes the invention protects the reactor core structure from possible damage that otherwise might be expected to occur if the force is applied to a rigid system. Further with respect to the operation of the invention, after the plunger 54 has completely blocked the guide post slots, controlled fluid discharge from the chamber 51 continues through the orifice 52 in the plate 53 until the applied force is fully absorbed. In this force absorption the coil spring 47 also participates to attenuate a share of the applied shock. Clearly, the combination of the coil spring 47, the orifice 52 and the progressively changing orifice area that is provided through the cooperative effect of the plunger 54 and the associated guide post slots produce a substantially better means for coping with these forces than any one or two of these components alone, even if the capacity of the individual components is increased to absorb the entire anticipated loading, in a way, moreover that actually removes parasitical neutron absorbing material from the reactor core. Thus, the hollow guide posts that characterize this invention eliminate inefficient neutron-absorbing matter from the reactor core in a way that nevertheless enhances the structural integrity of the core. Naturally, after the applied shock has been dissipated in the foregoing manner, the energy stored in the compressed coil spring 47 presses the fuel assembly 10 in a lengthwise direction away from the internal pad 32 unitl this motion is stopped through the action of the spring pad 30 and the stop 24. In most practical situations envisioned, it is expected that all of the shock attenuating guide posts in a reactor core structure will be involved in coping with major forces that might need to be withstood.