Patent Number: 052157059
Section: description

DETAILED DESCRIPTION The spring force gauge of the present invention, generally indicated at 10 in FIG. 1, is illustrated in position to measure the fuel rod-centering force of a spring 12 assembled with a pair of ferrules 14 and 16 of a nuclear fuel bundle spacer, generally indicated at 18. For details of the spacer construction, reference may be had to the above-cited Matzner et al. Patent, the disclosure of which is specifically incorporated herein by reference. As mentioned above in connection with this patent, spring 12 is a double-acting loop spring of generally elliptical shape having one resilient side 12a acting in ferrule 14 and a second resilient side 12b acting in ferrule 16. Thus, spring side 12a exerts a force on a fuel rod (not shown) inserted through ferrule 14 to bias it against inwardly formed stops 20, best seen in FIG. 2, thereby maintaining the fuel rod centered within the ferrule bore. Spring side 12b performs the same function with respect to a fuel rod inserted through ferrule 16. Gauge 10 is uniquely structured to accurately measure the fuel rod-centering force exerted by the individual spring sides 12a, 12b to determine if the spring force meets quality assurance standards. Thus, as seen in FIGS. 1 and 2, gauge 10 includes a probe, generally indicated at 22, having an elongated cylindrical body 24 for insertion into a ferrule, ferrule 16 in the drawing. The upper end of the probe body is joined with a handle 25 to accommodate manual manipulation of the gauge into spring force gauging position. A flange 26, extending laterally from the probe body, serves to mount a cylindrical alignment rod 28 via a shouldered bolt 30 extending through a clearance hole 32 in the flange and threaded into a counter-sunk and tapped axial bore 34 in the alignment rod. Thus, as probe 22 is inserted into ferrule 16, alignment rod 28 is inserted into ferrule 14. The diameters of the alignment rod and the probe body are each equal to the nominal diameter of a fuel rod, and thus their insertions into the ferrule bores simulate the presence of fuel rods. The shoulder of bolt 30 bottoms out on the shoulder of bore 34 before the bolt head can clamp down on flange 26 to provide for limited floating motion of the alignment rod relative to the probe body. This feature accommodates acceptably minor nonparallelism between the axes of the alignment rod and the probe body as spring 12 forces them against stops 20 and into centered portions in their respective ferrule bores. A plunger 36 is received in a transverse bore 38 formed in the probe body and is loosely captured therein by a roll pin 40 passing through a transversely elongated hole 42 in the plunger. Thus the plunger is free for limited reciprocation in its bore. The axial location of the plunger is such that its face 43, of a curvature corresponding to that of a fuel rod peripheral surface, confronts and is acted upon by side 12b of the spring, while spring side 12a is being loaded by the presence of the alignment rod in ferrule 14. The plunger is then subjected to the fuel rod-centering force exerted by spring side 12b in ferrule 16. To measure this force, the probe body is formed with an axially elongated slot 44 opening at its lower end into transverse 38 for accommodating an elongated arm 46 pivotally mounted to the probe body at a mid-length point by a roll pin 48. The lower end of the arm extends into a slot 50 formed in the plunger to present a contact surface in engagement with plunger at the bottom surface of the slot. The upper end of the arm is positioned to engage the tip 51 of a miniature load cell 52 threadedly received in a transverse tapped bore 54 formed in the probe body. The load cell may be of a conventional button strain gauge type, such as an Omega model LCK-25 available from Omega Engineering of Stamford, Connecticut. It is thus seen that the fuel rod centering force exerted by side 12b of the spring on plunger 36 is precisely communicated to the load cell 52 by pivoting arm 46. The resulting deflection of the load cell tip 51 is translated into an electrical signal proportional to the spring force, which is fed via wires 56 routed through handle 25 to a force-reading meter 58. Alternately, the load cell signals may be fed to a data acquisition system where they are computer processed and recorded for subsequent printout of the spring forces and spring locations for each spacer. The threaded mounting of the load cell permits adjustment of the transverse position of the load cell tip for calibration purposes and to adjustably position the plunger for fuel rods of differing nominal diameters. Completing the description of the gauge construction, an L-shaped spacer cover includes a vertical portion 60 affixed to probe body 24 by screws 61 and a lateral portion 62 having holes 63 through which alignment rod 28 and the cylindrical portion of the probe body extend. The lateral portion serves a spacing function by engaging the upper edges of the ferrules to control the depth of alignment rod-probe insertion and thus ensure that the plunger face is properly aligned with the spring side whose fuel rod-centering force is to be measured. The present invention thus provides a compact handheld gauge which is conveniently inserted into the multiple ferrules of a nuclear fuel bundle spacer in succession to accurately measure the fuel rod-centering spring forces acting in each ferrule. This quality assurance test can be performed expeditiously to qualify spacers at their manufacturing site for use in nuclear fuel bundles. It is seen from the foregoing Detailed Description that the objectives of the present invention are efficiently attained, and, since certain changes may be made in the construction set forth, it is intended that matters of detail be taken as illustrative and not in a limiting sense.