Patent Number: 047073250
Section: claims

1. A gauge plate for use in customizing replacement upper core plate inserts of a nuclear reactor of the type including a pressure vessel, a core barrel disposed within the pressure vessel, a lower internal structure disposed in the core barrel and including a baffle plate arrangement, and an upper internals structural package having an upper core plate at its lower end, with the upper core palte being provided with a plurality of peripheral grooves which each contain an insert machined to close tolerances for engaging respective approximately rectangular shaped guide pins extending radially inwardly from the inner surface of the core barrel for aligning the upper internals structural package relative to the lower internal structure, said gauge plate comprising: a circular metal plate of a known diameter corresponding substantially to that of the upper core plate of the nuclear reactor to be gauged; a plurality of U-shaped gauging slots formed in the peripheral surface of said gauge plate and extending between its major surfaces, said gauging slots being formed at locations corresponding to the respective locations of the radially inwardly directed guide pins of the reactor to be gauged and being of a known size sufficient to receive the respective guide pins with clearance on all sides; first means for positioning said gauge plate within the nuclear reactor vessel to be gauged, while it contains a baffle plate arrangement but not the upper internals structural package, at the normal elevation of the upper core plate inserts and the guide pins; second means, disposed on said gauge plate, for positioning said gauge plate relative to the baffle plate arrangement of the reactor to be gauged; gauge means in said gauge plate for determining the actual position of the gauge plate relative to the baffle plate arrangement; and remotely controlled measuring means, disposed on said gauge plate, for measuring the clearances between each of said U-shaped gauging slots and the adjacent surfaces of a respective guide pin and the clearance between the peripheral surface of said gauge plate and the inner surface of the core barrel adjacent each said gauging slot, and for providing an indication of the measured clearances at a remote location.  positioning the gauge plate in the core barrel of a nuclear reactor vessel containing a baffle plate arrangement but with the upper internals structural package removed, so that the gauge plate rests on the upper end of the baffle plate arrangement with the guide pins of the reactor vessel extending into the respective guaging slots of the gauge plate and with the positioning pins of the guage plats being properly positioned relative to the baffle plate arrangement; at each of said gauging slots and with the gauge plate in the same position, (a) measuring the difference between the peripheral surface of the gauge plate and the inner surface of the reactor core barrel, and (b) measuring the clearance between each of the three sides of the U-shaped gauging slot and the adjacent sides of the associated guide pin; and, with the gauge plate in the same position, determining the actual position of the gauge plate in relation to the baffle plates by inserting gauging means into each of the gauging holes.  positioning the gauge plate in the core barrel of a nuclear reactor vessel containing a baffle plate arrangement but with the upper internals structural package removed, so that the gauge plate rests on the upper end of the baffle plate arrangement with the guide pins of the reactor vessel extending into the respective gauging slots of the gauge plate and with the positioning pins of the gauge plate being properly positioned relative to the baffle plate arrangement; successively inserting gauge pins of known different size into one of the gauging holes to determine the largest diameter gauge pin which can be inserted, and then, leaving this largest diameter gauge pin inserted in its respective gauging hole; repeating said steps of successively inserting and leaving for each of the other gauging holes; and thereafter, at each of said gauging slots, (a) measuring the clearance between the peripheral surface of the gauging plate and the inner surface of the reactor core barrel, and (b) measuring the clearance between each of the three sides of the U-shaped gauging slot and the adjacent sides of the associated guide pin. 2. A gauge plate as defined in claim 1 wherein said gauge plate has a thickness substantially less than that of the upper core plate for the reactor. 3. A gauge plate as defined in claim 1 wherein said first means comprises a plurality of support pads disposed on one major surface of said gauge plate and positioned so as to be able to rest on the upper end of the baffle plates of the baffle plate arrangement of the reactor in which said gauge plate is to be used, said support pads being of a thickness so as to position said gauge plate at the elevation of the interface of the upper core plate inserts and the guide pins when said pads are resting on the upper ends of the baffle plates. 4. A gauge plate as defined in claim 3 wherein said second means comprises a plurality of positioning pins extending from said one major surface of said gauge plate, with said positioning pins being located on said gauge plate at respective positions corresponding to the outer most positions of the fuel assembly top nozzles of the reactor, and with each being of a length so that it can extend into the area enclosed by the baffle plate arrangement when said gauge plate is resting on the upper ends of the baffle plates. 5. A gauge plate as defined in claim 4 wherein eight of said positioning pins are provided in four pairs, with two of said pairs of being located along each of the respective cardinal axes of the surface of said gauge plate, with the two said pairs along each cardinal axis being diametrically opposed, and with said positioning pins of each said pair being symmetrically disposed with respect to the associated cardinal axis. 6. A gauge plate as defined in claim 4 wherein said gauging means includes a plurality of gauging holes extending through said gauge plate for receiving gauge pins, with said gauging holes being located at positions corresponding to the expected positions of respective baffle plates of the reactor in which the gauge plate is to be used. 7. A gauge plate as defined in claim 6 wherein said gauging holes are located at positions corresponding to the expected positions of respective baffle plates which cooperate with said positioning pins to position said gauge plate. 8. A gauge plate as defined in claim 6 wherein three of said gauging holes are provided with two of said gauging holes being located at positions corresponding to the positions of two adjacent baffle plates and the third gauging hole being located at a position corresponding to a baffle plate diametrically opposite one of said two adjacent baffle plates. 9. A gauge plate as defined in claim 8 wherein the center line of each of said gauging holes is displaced by a common given dimension from the expected position of the upper edge of the respective baffle plate in a direction perpendicular to the inner surface of the respective baffle plate. 10. A gauge plate as defined in claim 1 wherein said plate includes a plurality of relatively large area openings extending between the major surfaces in the interior portion of said plate. 11. A gauge plate as defined in claim 1 wherein four of said gauging slots are provided with said gauging slots being symmetrically disposed about the circumference of said gauge plate. 12. A gauge plate as defined in claim 1 wherein said measuring means comprises a respective set of four linear measurement devices mounted on the upper major surface of said guage plate adjacent each said U-shaped gauging slot, with three of said measurement devices each being disposed adjacent and perpendicular to a respective one of the three surfaces defining a respective U-shaped gauging slot and the fourth of said measuring devices being adjacent the periphery of said gauge plate and oriented in a radial direction. 13. A method of measuring and providing actual dimensions of the lower internals guide pin locations of a nuclear reactor vessel for use in customizing a replacement upper internals structural package so that it will mate with existing lower internal structure using a gauge plate as defined in claim 6 comprising the steps of: 14. A method as defined in claim 13 wherein the gauge plate includes at least three gauging holes with two of the gauging holes being located at positions corresponding to the positions of two adjacent baffle plates and the third gauging hole being located at a position corresponding to a baffle plate diametrically opposite one of the two adjacent baffle plates, and with the center line of each of the gauging holes being displaced by a common given dimension from the expected position of the upper edge of the respective baffle plate in a direction perpendicular to the inner surface of the respective baffle plate; and wherein said step of determining the actual position of the gauge plate relative to the baffle plates includes inserting gauge pins of known size into the gauging holes until the inner surface of the respective baffle plate is located. 15. A method as defined in claim 14 wherein said step of inserting includes successively inserting gauge pins of known different size into one of the gauge holes to determine the largest diameter gauge pin which can be inserted, and then, with this largest diameter gauge pin inserted in its respective gauge hole, repeating said step of successively inserting for each of the other gauge holes. 16. A method as defined in claim 15 wherein said step of determining the actual position of the gauge plate relative to the baffle plates is carried out before said steps (a) and (b). 17. A method of measuring and providing actual dimensions of the lower internals guide pin locations of a nuclear reactor vessel for use in customizing a replacement upper internals structural package so that it will mate with existing lower internal structure using a gauge plate including: a circular metal plate of a known diameter corresponding substantially to that of the upper core plate of the nuclear reactor to be gauged; a plurality of U-shaped gauging slots formed in the peripheral surface of said gauge plate and extending between its major surfaces, said gauging slots being formed at locations corresponding to the respective locations of the radially inwardly directed guide pins provided on the inner surface of the core barrel of the reactor to be gauged and being of a known size sufficient to receive the respective guide pins with clearance on all sides; a plurality of support pads disposed on one major surface of said gauge plate and positioned so as to be able to rest on the upper end of the baffle plates of the baffle plate arrangement of the reactor in which said gauge plate is to be used, with said support pads being of a thickness so as to position said gauge plate at the normal elevation of the interface of the upper core plate and the guide pins when said pads are resting on the upper ends of the baffle plates; a plurality of positioning pins extending from said one major surface of said gauge plate, with said positioning pins being located on said gauge plate at respective positions corresponding to the outer most positions of the fuel assembly top nozzles of the reactor, and with each being of a length so that it can extend into the area enclosed by the baffle plate arrangement when said gauge plate is resting on the upper ends of the baffle plates; at least three gauging holes extending through said gauge plate for receiving gauge pins, with two of said gauging holes being located at positions corresponding to the expected positions of two adjacent baffle plates and the third gauging hole being located at a position corresponding to a baffle plate diametrically opposite one of said two adjacent baffle plates, and with the center line of each of said gauging holes being displaced by a common given dimension from the expected position of the upper edge of the respective baffle plate in a direction perpendicular to the inner surface of the respective baffle plate; said method comprising the steps of: 18. A method as defined in claim 17 wherein said steps of measuring and said step of inserting are controlled and carried out from a remote location.