Patent Number: 048184721
Section: description

Referring now to the figures of the drawings in detail and first, particularly, to FIG. 1 thereof, there is seen a component in the form of a vessel DB of a heat exchanger for a nuclear power plant which has a lower part 1.1 and a cover 1.2, to be mounted on a vessel flange 1.11 normal to the longitudinal axis 1' of the vessel; the cover has an annular flange 1.21 and screws 1.22 distributed over the periphery thereof in the vicinity of the cover flange. The cover screws 1.22 are anchored in the cover flange 1.21 of the bottom portion in suitably threaded bores. The vessel DB, hereinafter referred to as the pressure vessel DB, has a substantially hollow cylindrical shape with a spherical bottom 1.13 and a conical transition 1.14 between the cylindrical portion and the spherical bottom 1.13. A connector portion of the pressure vessel, where line connectors or sockets 2 are disposed, is located in the vicinity of the reinforced cover flange 1.21. The pressure vessel DB is mounted on a supporting ring structure with support claws 3. Reference numeral 5 designate a biological shield in the form of a concrete structure; reference numeral 6 designates a concrete structure on the bottom of the reactor building; and an annular gap 7a remains between a jacket or shell 8c and the pressure vessel DB, while an approximately hollow-conical space 7b remains in the vicinity of the spherical bottom 1.13. A portion 7a1 of the annular gap 7a and a portion 7b1 of the space 7b on the bottom are filled with a sheathing 8 for the pressure vessel DB, which is shown in cross section. The sheathing 8 has a thickness which permits the sheathing to perform a supporting function for a receptacle or decontamination tank for at least a part of a component DB that is to be dismantled or disintegrated into individual pieces 9. However, prior to supplying the sheathing, the cover 1.2 along with a cover insulating hood 11 seen in FIG. 2 is raised and moved into a temporary storage position. For shielding reasons, the pressure vessel DB is also filled with water to a level just below the flange 1.11, such as up to a level line 12. For the sake of good viewing conditions, it is favorable for the water to be cleaned continuously during the dismantling or disintegration by means of a water cleaning system, which has a pump 26 and filter 27. The component DB is then dismantled or disintegrated from above by a processing method involving removal into the individual pieces 9, using a non-illustrated manipulator having a tool head; the individual pieces are defined by removal or cutting lines in the form of horizontal system lines 9a and surface or jacket lines 9b, which will be described in further detail below. The sheathing 8 is advantageously formed of shielding material, in particular a concrete shielding jacket provided with a reinforcement 8a. It is also possible to use a tough plastic material capable of being cast or injected, as the sheathing. The plastic material is preferably reinforced as well, for instance with a network of cables formed of glass-fiber-reinforced polyester which are capable of absorbing high tensile strain. Before a network of this kind can be lowered into the annular gap and the integral casting can be started, all of the obstructions that may possibly be present in the annular gap must be removed. The network is then braced on the bottom in basket-like fashion by means of fixtures, so that it encompasses the entire lower portion of the pressure vessel DB. Subsequently or even previously, the bottom region of the concrete structure 6 surrounding the pressure vessel DB is suitably provided with a separation layer 8b, which is applied by remote control. The layer 8b may be in the form of separation foils, which are disposed on the inner wall of the shell or concrete structure together with the reinforcement network for the sheathing. The material for the sheathing itself is then introduced by casting or by extrusion filling of the spaces 7a1 and 7b1, and the wedge-shaped spaces 7b2 in the vicinity of the spherical bottom 1.13 are also suitably filled by means of filler pieces, since complete filling by casting is not necessary in these areas. Naturally, before the shielding water is introduced into the pressure vessel DB, the line connectors 2, which are truncated elements produced by severing the remaining parts of the primary coolant lines, are sealed off from inside by sealing bodies 2a; these connectors are likewise jacketed or lined by the sheathing 8, as are the support claws 3. The line connectors 2 and/or the claws 3 can then be used for attaching supporting cables of a non-illustrated construction crane. The pressure vessel DB and the sheathing 8 are then prepared to such an extent that with a non-illustrated manipulator and tool head, it is possible to move into the interior of the vessel from above. In order to perform the dismantling or disintegration into the individual pieces 9 along the removal or cutting lines 9a, 9b, chip-removing methods such as turning, milling, sawing or arc sawing are suitable. The advantage provided by such a process is that the water that fills the pressure vessel DB simultaneously provides the required cooling. However, it is also possible to use a chemical or electrochemical erosion method under water. If an electrolyte suitable for electrochemical erosion is used as a shielding liquid, then this liquid need merely be set into circulation by suitable pumps at the locations at which the electrodes are in operation at a particular time. As the system and surface lines 9a, 9b show, the component DB is dismantled or disintegrated into many wall pieces 9 by making circumferential grooves and/or longitudinal grooves or slits. It is possible for the component DB to first be dismantled or disintegrated into individual courses 90 by removal along the inside system or circumference lines 9a. The work is suitably performed progressively from top to bottom. The upper courses can then be lifted out as needed and moved to a temporary storage location. However, if the sheathing 8 is dimensioned in such a way as to support the entire weight of the component DB, then after suitable dismantling or disintegration of the component into the courses 90, dismantling or disintegration into the individual wall pieces 9 is suitably performed by tooling, machining or erosion along the surface lines 9b. The work is then preferably performed from top to bottom. With the use of such a method, further processing of portions located farther down cannot be hindered by wall pieces that become detached by themselves, because the separated wall pieces are held firmly by the adhesion of the wall pieces to the sheathing 8, unless they are removed by a gripping tool. Once the dismantling or disintegration of the component DB into the individual wall and bottom pieces 9 has been completed, some of the shielding water can be pumped out, because the pieces 9 can be piled up in the vicinity of the spherical bottom. A closure cover, preferably made of the same casting compound as the sheathing 8, is then suitably placed on the upper rim of the sheathing 8 and joined to it, preferably by being cast onto it. As FIG. 2 shows, the method according to the invention can also be used in the dismantling or disintegration of a reactor pressure vessel. Prior to supplying the sheathing, the cover 1.2 of the reactor pressure vessel, together with control rod tubes 10 and the cover insulating hood 11, is raised and moved to a temporary storage position. The inner periphery of the biological shield 5 and the bottom region of the concrete structure 6 surrounding the pressure vessel DB are provided with the separation layer 8b, which is preferably applied by remote control using spray lances. The same removal process as that described for the lower part 1.1 of the vessel is preferably also performed for the cover 1.2 of the reactor pressure vessel shown in FIG. 3; that is, the cover 1.2 is set in a hollow concrete form 1.3 by connectors 1.23, sheathed with a supporting sheathing 8 and then crushed. In FIG. 4, a reactor pressure vessel 1 is disposed inside a biological shield 28, which forms a reactor pit (concrete shielding) 16 seen in FIG. 5. A bottom plate 13, which may be made of steel, is disposed on the bottom of the shield 28 below the reactor pressure vessel. The vessel is provided with substitute or replacement supports or braces 14 for wet dismantling or disintegration of the reactor pressure vessel 1. The upper supports or braces (support claws) and all of the parts that discharge into the reactor pressure vessel 1, especially lines 1c shown in FIG. 5, are removed, as are support structures 1f in the upper region of the reactor pressure vessel 1, which are also shown in FIG. 5. The shell or enclosure tube 15 shown in FIG. 4 is then introduced between the reactor pressure vessel 1 and the biological shield 2. The diameter of the enclosure tube 15 is adapted to the diameter of the bottom plate 13 inserted into the reactor pit; the bottom plate can also be in the form of a tank or tub. Once the enclosure tube 15 which is provided with a manhole 15b has been introduced, it is joined tightly to the bottom plate 13 which is built in underneath the reactor pressure vessel 1, such as by means of a welded seam 13a. A flange 15a at the top of the enclosure tube 15 is joined to a flooding pit or well 24 by means of a seal 17. As a result of the flooding of the enclosure tube 15, the outside of the reactor pressure vessel is underwater as well and in this way it can be separated into suitable sections. The sequence of the steps in the dismantling and crushing of the reactor pressure vessel may, for instance, be in the following order (with the fuel assemblies and built-in core parts removed and the reactor and the flooding chamber flooded): (A) lowering of the water level far enough that it is just below the lower edge of a flange 1e of the reactor pressure vessel, as seen in FIG. 5; (B) installation of a seal 1b shown in FIG. 4 on the inside of the coolant inlet and outlet connectors and other auxiliary lines from the inside of the reactor pressure vessel 1 towards the outside; (C) introduction and completion of the bottom plate 13 underneath the reactor pressure vessel 1, installation of the replacement or substitute supports or braces 14 on the bottom of the reactor pit; (D) disassembly of a seal 20 shown in FIG. 5 between the flange of the reactor pressure vessel 1 and the lining of the flooding chamber; (E) severing of all of the parts of the reactor pressure vessel that obstruct the installation of the enclosure tube (such as the upper support structures 1f and the connectors of the lines 1c); (F) severing, for instance by milling or arc sawing while dry, lifting out and removing the non highly-radioactive reactor pressure vessel flange 1e shown in FIG. 5; (G) installation of the enclosure tube 15 seen in FIG. 4; (H) sealing the enclosure tube 15 with the bottom plate 13, for instance by welding; (I) possibly sealing the enclosure tube 15 with the flooding pool 24 by installation of the seal 17; (K) flooding the enclosure tube 15 up to the vicinity of the upper end thereof; and (L) annularly severing wall pieces 18 of the reactor pressure vessel along separation lines 19 and crushing them, as well as thermal insulation 25 that may still be present on the outside of the reactor. The enclosure tube 15 is used as a sealing element with respect to the reactor pit 16 and has the following functions: (a) Holding the water surrounding the reactor pressure vessel. The water is used for shielding the radiation of the reactor pressure vessel, the sections thereof and the biological shield (liner, reinforcing irons), toward the top; (b) Catching secondary waste (contaminants, etc., that are filtered out) which is produced during the separation of the reactor pressure vessel by the separating equipment located in the enclosure tube; (c) Providing a temporary storage location for the reactor pressure vessel sections and as a transfer site; (d) Holding the separation equipment necessary for the dismantling or disintegration of the reactor pressure vessel; (e) Providing water which serves as a coolant for the separating equipment; (f) Avoidance of spreading contamination into the biological shield; and (g) Shielding the radiation of the concrete reactor pit (biological shield) in the course of possible installation of a new reactor pressure vessel. The severing of the inlet and outlet connectors and of the reactor flange and reactor pressure vessel brackets, and the introduction of the enclosure tube 15, are performed from locations that have only a low radiation exposure. Instead of the steel bottom plate 13, a tub or tank-like bottom plate in the form of a lining 21 formed of plastic, such as epoxy resin with a glass-fiber laminate, can be disposed on the bottom of the reactor pit after an enclosure tube 15 with a manhole 15b has been introduced, as seen in FIG. 6. The plastic lining 21 is drawn upward somewhat at the lower end of the enclosure tube 15, to provide suitable sealing. Another possibility is shown in FIG. 7, which shows a boiling water reactor, which is supported by a pedestal frame 22. In this case, after severing all of the parts that would hinder the installation of the enclosure tube 15, the enclosure tube 15 is disposed between the biological shield 28 and the pressure vessel 1. The enclosure tube 15 is joined tightly to the bottom 1d of the reactor pressure vessel 1 by welding or by casting with sealing compound 23, especially a rubber compound. The reactor pressure vessel 1 can then be dismantled mechanically or by use of an arc saw under water, down to the bottom 1d. The bottom 1d itself can be further disassembled while dry, for instance, because the activity is low. This variation is possible wherever the vessel bottom 1d is supported. It is suitable for the connection of the enclosure tube 15 with the reactor pressure vessel 1 to be disposed just above the pressure vessel support or brace (pedestal frame 22). The enclosure tube, which is shortened at the top, can remain in the reactor pit after the installation of a new reactor.