Patent Number: 053435060
Section: claims

1. A nuclear reactor installation, comprising: a reactor pressure vessel, a reactor core in said reactor pressure vessel;  a supporting and protective structure supporting said reactor pressure vessel and surrounding said reactor pressure vessel on the bottom and laterally, said supporting and protective structure having a bottom region and a circumferential wall;  a core catcher device for said reactor core having a collecting basin for a core melt being installed below said reactor pressure vessel, said collecting basin having a bottom wall and a jacket wall being respectively separated from said bottom region and said circumferential wall of said supporting and protective structure by a spacing gap;  cooling channels disposed in said spacing gap at said bottom wall and said jacket wall for exterior cooling of said collecting basin with a cooling liquid; and  turbulence bodies disposed in a surface region of said bottom wall for generating a turbulent flow of the cooling liquid flowing from the inside to the outside over said bottom wall toward said jacket wall.  a. a lower insulating portion lining said sacrificial layer of said collecting basin and enclosing said bottom cup of said reactor pressure vessel,  b. a central insulating portion lining said inner periphery of said shielding ring, and  c. an upper insulating portion extending from said shielding ring to the area of said cover portion gap of said reactor pressure vessel and being penetrated by said main coolant connection.  the outer periphery of said upper insulating portion and the inner periphery of said circumferential wall of said supporting and protective wall,  the outer surfaces of said support ring structure, and  said outlet ring channels leading into said containment and said exhaust air filter installation.  a reactor pressure vessel, a reactor core in the reactor pressure vessel, a primary circuit having main coolant lines leading to the reactor pressure vessel, pressure reservoirs communicating with the main coolant lines; a supporting and protective structure supporting the reactor pressure vessel and surrounding the reactor pressure vessel on the bottom and laterally, the supporting and protective structure having a bottom region and a circumferential wall; a core catcher device for the reactor core having a collecting basin for a core melt being installed below the reactor pressure vessel, the collecting basin having a bottom wall and a jacket wall being respectively separated from the bottom region and the circumferential wall of the supporting and protective structure by a spacing gap; a collecting basin cooling system having cooling channels disposed in the spacing gap at the bottom wall and the jacket wall for exterior cooling of the collecting basin with a cooling liquid; turbulence bodies disposed in a surface region of the bottom wall for generating a turbulent flow of the cooling liquid flowing from the inside to the outside over the bottom wall toward the jacket wall; and a cooling water reservoir disposed outside the supporting and protective structure, an inlet channel configuration connecting the cooling channels at the bottom wall to the cooling water reservoir and an outlet channel configuration connecting the cooling channels at the jacket wall to the cooling water reservoir, with a lift generating a naturally circulating flow through the cooling channels when the collecting basin is hot and the cooling channels are filled with water;  the method which comprises:  maintaining a cooling water level of the cooling water reservoir at a low water level, during normal operation of the nuclear reactor installation, at which no cooling water can reach the inlet channel configuration of the collecting basin cooling system,  feeding emergency cooling water, when a leak occurs in the primary circuit, from the pressure reservoirs to be activated as a function of pressure of the primary circuit into the main coolant lines of the reactor pressure vessel, by feeding the emergency cooling water through the leak location and, if necessary, parallel thereto through further feed locations into the cooling water reservoir, and  maintaining a sufficient water volume in the pressure reservoirs to lift the cooling water level of the cooling water reservoir up to a high water level for causing cooling water from the cooling water reservoir to reach the inlet channel configuration and from there the spacing gap of the collecting basin cooling system for filling the cooling system up to the level of the outlet channel configuration, for starting a naturally circulating flow, when the collecting basin is hot, from the cooling water reservoir through the inlet channel configuration to the cooling channels at the bottom wall and the jacket wall of the cooling system and from there through the outlet channel configuration back to the cooling water reservoir. 2. The nuclear reactor installation according to claim 1, including a cooling water reservoir disposed outside said supporting and protective structure, an inlet channel configuration connecting said cooling channels at said bottom wall to said cooling water reservoir and an outlet channel configuration connecting said cooling channels at said jacket wall to said cooling water reservoir, said cooling water reservoir forming a reactor housing sump. 3. The nuclear reactor installation according to claim 1, including a cooling water reservoir disposed outside said supporting and protective structure, an inlet channel configuration connecting said cooling channels at said bottom wall to said cooling water reservoir and an outlet channel configuration connecting said cooling channels at said jacket wall to said cooling water reservoir, with a lift generating a naturally circulating flow through said cooling channels when said collecting basin is hot and said cooling channels are filled with water. 4. The nuclear reactor installation according to claim 1, including a reactor cavern being bounded by said bottom region and said circumferential wall of said supporting and protective structure, said reactor pressure vessel being disposed in said reactor cavern at vertical and lateral distances from said bottom region and said circumferential wall, said reactor pressure vessel being seated in said supporting and protective structure, and said jacket wall of said collecting basin being disposed at a height extending at least approximately to a lower edge of said reactor core. 5. The nuclear reactor installation according to claim 1, wherein said collecting basin is seated on said bottom region of said supporting and protective structure by said turbulence bodies. 6. The nuclear reactor installation according to claim 1, including support bodies with which said collecting basin is seated on said bottom region of said supporting and protective structure. 7. The nuclear reactor installation according to claim 1, including separate support bodies, said collecting basin being seated on said bottom region of said supporting and protective structure by said turbulence bodies and said separate support bodies. 8. The nuclear reactor installation according to claim 1, wherein said collecting basin is constructed in the form of a crucible with said bottom wall being curved towards the bottom and the outside, said collecting basin has an upper edge, said collecting basin has a rounded-off edge area forming a transition from said bottom wall to said jacket wall, and said jacket wall tapers slightly conically from said rounded-off edge area to said upper edge. 9. The nuclear reactor installation according to claim 8, wherein said bottom wall of said collecting basin has a lowest central area and widens in the shape of a flat envelope of a cone from said lowest central area to said edge area defining intersecting surfaces being located in axial-radial intersecting planes and extending with a slight angle of slope relative to the horizontal. 10. The nuclear reactor installation according to claim 9, including a cooling water reservoir disposed outside said supporting and protective structure, an inlet channel configuration connecting said cooling channels at said bottom wall to said cooling water reservoir and an outlet channel configuration connecting said cooling channels at said jacket wall to said cooling water reservoir, and an inlet chamber through which said inlet channel configuration discharges into said cooling channels at said bottom wall in said central area, said cooling channels at said bottom wall extending outwardly from said inlet chamber as far as said edge area of said collecting basin, and one of said cooling channels at said jacket wall extending upward, adjoins said edge area at said jacket wall and terminating in said outlet channel configuration. 11. The nuclear reactor installation according to claim 10, including a chamber receiving said cooling water reservoir, said inlet channel configuration penetrating through said bottom region of said supporting and protective structure and extending from said chamber as far as said central area of said bottom wall of said collecting basin, and said outlet channel configuration penetrating through said circumferential wall of said supporting and protective structure, forming a continuation of said cooling channel at said jacket wall and terminating in the vicinity of an upper level of said cooling water reservoir. 12. The nuclear reactor installation according to claim 1, wherein said collecting basin includes: a base body in the form of a crucible being formed of a temperature-resistant steel alloy material, a protective shell lining said bottom wall and said jacket wall inside said crucible for protecting said crucible material against attacks by the melt, and a sacrificial material deposit following said protective shell as another protective layer on said crucible, said sacrificial material deposit being sufficient in amount for reacting with a maximally possible volume of the core melt entering said collecting basin in case of a possible malfunction. 13. The nuclear reactor installation according to claim 12, wherein said protective shell is formed of at least one alloy selected from the group consisting of MgO, UO.sub.2 and ThO.sub.2. 14. The nuclear reactor installation according to claim 12, wherein said sacrificial material deposit is a masonry structure of shielding concrete blocks. 15. The nuclear reactor installation according to claim 1, wherein said turbulence bodies are delta wings in the shape of prisms having triangular surfaces being fastened on said bottom region of said supporting and protective structure opposite said collecting basin bottom wall with a cooling gap therebetween. 16. The nuclear reactor installation according to claim 1, wherein said turbulence bodies are pipe sockets having ends facing said bottom wall of said collecting basin, said ends of said pipe sockets having channel recesses formed therein for generating partial cooling water flows bathing said bottom wall in the area of said pipe sockets. 17. The nuclear reactor installation according to claim 16, wherein said channel recesses are U-shaped, each of said pipe sockets has two of said U-shaped channel recesses aligned in the flow direction, and said pipe sockets have angular ends at said U-shaped recesses for increasing turbulence. 18. The nuclear reactor installation according to claim 1, including a shielding ring being installed above and adjoining said collecting basin between said circumferential wall of said supporting and protective structure and the outer periphery of said reactor pressure vessel. 19. The nuclear reactor installation according to claim 18, wherein said shielding ring is anchored on said circumferential wall of said supporting and protective structure. 20. The nuclear reactor installation according to claim 18, wherein said supporting and protective structure is formed of prestressed concrete with a steel reinforcement, and said shielding ring is formed of shielding concrete and a steel reinforcement being united with said steel reinforcement of said supporting and protective structure into a uniform steel reinforcement system. 21. The nuclear reactor installation according to claim 12, wherein said reactor pressure vessel has an outer periphery, a lower part with a bottom cup, a cover portion gap and a main coolant connection, and including a shielding ring having an inner periphery, being installed above and adjoining said collecting basin between said circumferential wall of said supporting and protective structure and the outer periphery of said reactor pressure vessel, and a heat insulation surrounding said lower part of said reactor pressure vessel at a distance and being substantially divided into three insulating portions merging into each other, said insulating portions being: 22. The nuclear reactor installation according to claim 1, including a cooling water reservoir disposed outside said supporting and protective structure, an inlet channel configuration connecting said cooling channels at said bottom wall to said cooling water reservoir and an outlet channel configuration connecting said cooling channels at said jacket wall to said cooling water reservoir, a dual air and water exterior cooling system of said collecting basin for air cooling of said reactor pressure vessel during normal operation of the nuclear reactor installation when said exterior cooling system is dry, a cooling air source connected to said inlet channel configuration, and a cooling air sink connected to said outlet channel configuration. 23. The nuclear reactor installation according to claim 1, including a cooling water reservoir disposed outside said supporting and protective structure, an inlet channel configuration connecting said cooling channels at said bottom wall to said cooling water reservoir and an outlet channel configuration connecting said cooling channels at said jacket wall to said cooling water reservoir, a thermal insulation enclosing said reactor pressure vessel, a dual air and water exterior cooling system of said collecting basin for air cooling of said thermal insulation during normal operation of the nuclear reactor installation when said exterior cooling system is dry, a cooling air source connected to said inlet channel configuration, and a cooling air sink connected to said outlet channel configuration. 24. The nuclear reactor installation according to claim 23, including a containment, an exhaust air filter installation, a shielding ring being installed above and adjoining said collecting basin between said circumferential wall of said supporting and protective structure and the outer periphery of said reactor pressure vessel, said circumferential wall having an inner periphery, a support ring structure for said reactor pressure vessel having outer surfaces, a heat insulation for said reactor pressure vessel having a lower insulating portion, a central insulating portion and an upper insulating portion with an outer periphery, main coolant lines for said reactor pressure vessel having an outer periphery, wall openings in said supporting and protective structure having an inner periphery, outlet ring channels formed between the outer periphery of said main coolant lines and said inner periphery of said wall openings, and a further air cooling system for said reactor pressure vessel in addition to said exterior dual cooling system, having inlet channels for supplying air to said further air cooling system, said inlet channels penetrating said circumferential wall of said supporting and protective structure and said shielding ring and terminating in an upper cooling air chamber, said upper cooling air chamber extending outside said upper insulating portion to said support ring structure, for guiding upwardly flowing cooling air in several partial flows along cooling surfaces, said cooling surfaces being: 25. The nuclear reactor installation according to claim 24, wherein the outer surfaces of said support ring structure include support arms, lug supports of the reactor pressure vessel being supported by said support arms, and seats of said support ring structure. 26. The nuclear reactor installation according to claim 12, wherein said collecting basin has a multi-layer construction and said crucible has a wall, and including a heat insulation for said reactor pressure vessel having a lower insulating portion, a central insulating portion and an upper insulating portion, a cooling liquid reservoir disposed outside said supporting and protective structure, at least one melt cooling tube penetrating said collecting basin in an upper half of said jacket wall and extending through said crucible wall, said protective layer, said sacrificial material deposit and said thermal insulation, said at least one melt cooling tube having an inlet side, an inner end and a melting plug sealing said inner end, said at least one melt cooling tube extending with a gradient from the outside to the inside and communicating on said inlet side with said cooling liquid reservoir, for heating said melting plug to its melting temperature with the core melt present in said collecting basin, causing said melting plug to melt and opening a flow channel to the surface of the core melt for cooling liquid. 27. A method for starting and maintaining exterior cooling of a core catcher device of a nuclear reactor installation having: