Patent Number: 051456370
Section: claims

1. A maintenance procedure for a nuclear reactor, said reactor including a vessel having a top, a bottom, and a wall, said reactor having a core within said vessel, said reactor having an instrumentation guide assembly, said instrumentation guide assembly including an incore housing extending through said bottom, said incore housing being bonded to said vessel by a weld, said instrumentation guide assembly also including a guide tube above, coaxial to and bonded to said incore housing, said guide tube extending at least partially through said core, said reactor having an instrumentation module which can be inserted into said core through said guide tube for monitoring said core, said procedure comprising the steps of: shutting down said reactor;  removing said top;  removing said instrumentation module from said vessel;  inserting an ultrasonic probe and an attached shaft from above so that said shaft extends through said core and is at least partially immersed in water and through said guide tube and so that said probe extends at least partially into said incore housing;  mounting a drive unit above said core, said drive unit being coupled to said probe via said shaft;  operating said drive unit so that it moves said ultrasonic probe vertically and circumferentially in alternation within said incore housing while said ultrasonic probe is activated to detect defects in said weld;  removing said probe from said vessel;  inserting a new instrumentation module into said guide tube;  replacing said top; and  restarting the reactor.  lowering a probe into the interior of said incore housing from above, said probe being mechanically coupled to a scanning drive mechanism via a shaft extending through said core;  clamping said scanning drive mechanism to a top guide at the top of a reactor core of said reactor pressure vessel so as to define a reference circumferential position of said probe within and relative to said reactor pressure vessel, and adjusting the vertical distance between said drive mechanism and said probe so as to define a reference vertical position of said probe within and relative to said reactor pressure vessel; and  raster scanning said weld by alternating sweeps in one of the vertical and circumferential dimensions with incremental movements in the other of said dimensions, and while raster scanning  said probe includes multiple transducers and multiple eddy current coils  all of said multiple transducers are pulsed during the entire ultrasonic examination;  a plurality of said multiple transducers have the same focal point during the ultrasonic examination to interrogate the same region simultaneously; and  all of said said multiple eddy current coils are energized during the entire eddy current examination.  wherein said drive mechanism moves said probe to perform said examination with said multiple eddy current coils and with said multiple transducers so as to cause all of said transducers and all of said eddy current coils to travel from above the highest level of said weld to below the lowest level of said weld during their respective examinations.  a probe with at least one ultrasonic transducer;  a drive mechanism including  electronic means for causing said drive mechanism to alternatively sweep said probe in one of a vertical dimension and a circumferential dimension and step in the other of said dimensions, said electronic means activating and taking data from said ultrasonic transducer, said electronic means coordinating vertical and circumferential movement of said probe with said data collection so the position of any detected defects can be specified. 2. A method of performing a non-destructive examination of a weld attaching an incore housing to a bottom head of a reactor pressure vessel, wherein said weld at least partially surrounds the external periphery of said incore housing, said method comprising the steps of: 3. A method as recited in claim 2 further comprising examining the interior surface and near surface thickness of said incore housing using at least one eddy current coil with said probe. 4. A method as recited in claim 3 wherein: 5. A method as recited in claim 4 wherein said incore housing at least partially penetrates said bottom head; and 6. A method as recited in claim 5 wherein said drive mechanism moves said probe so that all of said transducers and all of said eddy current coils travel from at least 40 millimeters above the highest level of said weld to at least 40 millimeters below the lowest level of said weld. 7. A method as recited in claim 6 wherein said examinations are done with vertical sweeps followed by rotations of about 5.degree. until said probe has rotated at least 360.degree.. 8. A method as recited in claim 7 wherein said probe includes at least one longitudinal wave transducer that faces normal to the surface of said incore housing, said respective examinations beginning with said longitudinal transducer facing so as to traverse past the highest level of said weld in the first vertical sweep of said ultrasonic examination. 9. A system for the non-destructive examination of welds between an incore housing and a bottom head of a reactor pressure vessel of a boiling-water reactor, said system comprising: 10. A system as recited in claim 9 wherein said vertical adjustment means includes an extension tube coupling said drive shaft and said probe, said adjustment means also including extension locking means for holding said extension tube in a fixed vertical position, said extension being free to rotate 360.degree. and slide lengthwise through its entire length in said shaft prior to locking. 11. A system as recited in claim 10 wherein said probe includes an eddy current coil. 12. A system as recited in claim 11 wherein said probe includes multiple ultrasonic transducers having the same focal point, said probe also including multiple eddy current coils. 13. A system as recited in claim 12 wherein said multiple eddy current coils include coils of both the absolute and differential type. 14. A system as recited in claim 13 wherein said probe comprises six ultrasonic transducers and four eddy current coils. 15. The system of claim 14 wherein, of said six ultrasonic transducers, three are oriented so their beams are perpendicular to the length of said probe. 16. A system as recited in claim 15 wherein a hoist cable capable of raising and lowering said drive mechanism, said extension, and said probe is attached to said drive mechanism.