Patent Number: 
Section: description

As shown in FIGS. 1 and 2, an exemplary RPV 100 is ellipsoid in shape and includes a vessel shell 101, an upper head 102, an upper instrumentation and support assembly 103, a pair of lifting lugs 104, a pair of head studs 105, O-ring seals 106, an upper support plate 107, control rod guide tubes 108, an upper core plate 109, a lower core plate 110, a lower core support plate 111, a lower core support column 112, a core barrel 113, neutron shield pads 114, former plates 115, core baffle plates 116 and an interior surface 117 which is usually clad with a thin stainless steel liner. FIGS. 3, 4 and 7 show an RPV 100 that has been prepared for decommissioning and removal according to the method of the present invention by attachment of shielding plates. The RPV 100 is clad with a two inch thick shield plate 201 surrounding the upper portion of the vessel shell 101 around the outlet and inlet nozzles 204, 205, a five inch thick shield plate 202 surrounding the middle portion or core area of the vessel shell 101, a one inch thick shield plate 203 around the lower portion of the shell 101 (beneath the lower core support plate 111), outlet nozzles 204, inlet nozzles 205, a drain 206, incore penetrations 207, a head vent 208, Control Rod Drive Mechanism (xe2x80x9cCRDMxe2x80x9d) penetrations 209, flange monitoring tubes 210, a transport cradle 212 and longitudinal restraint jaws 213 which are tightened to hold the RPV 100 in place during transport. Impact limiters 211 can be installed on each end of the RPV 100 to prevent knocking or bumping of the RPV 100 during transport. As shown in FIGS. 3 and 6, outlet and inlet nozzles 204, 205 are covered by respective closure plates 404 and 405. Similarly, a drain opening is covered by a closure plate 406, an incore opening 207 is covered by a closure plate 407, a head vent opening 208 is covered by a closure plate 408, a CRDM opening 209 is covered by a closure plate 409 and a flange monitoring tube 210 is covered by a closure plate 410. The closure plate material can be ASME SA-240, Type 304L, ASME SA-516 GR. 70, or any suitable alloy providing requisite radiation shielding and welding characteristics. The closure plates 404-410 are welded to the RPV 100 so that the closure plates 404-410 cover their respective openings 204-210. FIG. 4 provides details of shielding on an RPV 100 and illustrates typical longitudinal seam welds 501 between each respective two inch thick shield plate 201 or between each respective five inch thick shield plate 202 and circumferential seam welds 502 between a two inch thick shield plate 201 and a five inch thick shield plate 202. FIG. 4 also illustrates typical longitudinal seam closure plates 503 and typical circumferential seam closure plates 504. Longitudinal seam welds that do not use the closure plates 503 are also used on some of the seams. FIG. 5 shows a cross section of the RPV 100 housing Low-Density Cellular Concrete (LDCC) 600. The void space inside the RPV 100 should be limited to  less than 15% of the total volume of the RPV 100. LDCC 600 is used to fill the RPV 100. LDCC 600 is a heterogeneous mixture of organic surfactants/admixtures, portland cement, water and air and is sensitive to overpressurization. For an approximately 42 foot RPV 100, 130 megagrams (Mg) of 10xc2x0 C. liquid LDCC 600 can be injected into the drained RPV 100 (weighing xcx9c907 Mg) still positioned in the vertical position. Due to the high internal metal temperature, caused by component decay heat of the reactor vessel, compensating action should be taken to cool the inside of the RPV 100 prior to injection of the LDCC 600 into the vessel. A grout chiller system circulates air from outside the containment region into the RPV 100 to remove heat from the inside of the RPV 100. Before exiting the containment region, exhaust air passes through a cooling coil, high efficiency particulate air (HEPA) filters, and an exhaust fan. The grout chiller system is put into operation prior to the injection of LDCC 600 into the RPV 100 and can lower RPV 100 internal metal temperatures to  less than 75xc2x0 C. The LDCC 600 is prepared in batches on-site using special foaming agents and curing additives, pumped into the containment building and routed to proper RPV 100 injection ports. The density of the LDCC is within a safety range of 0.721 to 1.041 g/cm3. Prior to installing the shield plates 201, 202, the RPV 100 is allowed to vent and cool. In addition, closure plates, for example the drain closure plate 406, can be removed to verify that the RPV 100 includes a requisite amount of the LDCC 600, that there are no empty spaces in the RPV 100, and that no free standing water is in the RPV 100. The two inch thick shield plate 201 is mechanically fastened around the main nozzles of the RPV 100. The 5 inch thick shield plate 202 is mechanically closed around the RPV 100. The 5 inch thick shield plate 202 can be mechanically closed around the RPV 100 by lowering the RPV 100 into a void enclosed around its circumference/perimeter by the 5 inch thick shield plate 202 and subsequently mechanically fastening the 5 inch thick shield plate 202 to the RPV 100. The mechanical fasteners are removed after the shield plates are welded as described below. The shield plates 201, 202 are not welded to the RPV 100 so as to avoid exposing workers to high radiation doses and so that the integrity of the RPV 100 is not compromised. Two inch and five inch shield plate 201, 202 vertical seams are welded and then the five inch shield plate 202 is welded to the two inch shield plate 201 on the circumference as shown in FIG. 11. The shield plate material can be steel or the like. As shown in FIG. 7, the RPV 100 may now be removed and placed on its side in preparation for removal and disposal. The final step is to transport the RPV 100 to a burial site by means of a barge or the like. The RPV 100 package can be buried in a trench or the like. While this invention has been described in terms of specific embodiments, this invention, including this disclosure and appended claims, is not so limited and is to be construed in accordance with the full spirit and scope of the invention including alternatives and modifications made apparent to those of skill in the art.