Patent Number: 046648712
Section: claims

1. A nuclear power installation of compact construction, comprising: a high-temperature pebble bed reactor, having a core of spherical fuel elements, and a reflector which surrounds the core and which has a side section;  a multicomponent cylindrical steel pressure vessel surrounding said reactor including a retracted upper section, a cover and a main body;  a heat utilization system positioned in the retracted section of the pressure vessel, above the reactor in the pressure vessel, comprising only one steam generator, wherein said heat utilization system uses a cooling gas which flows from bottom to top through the core and the pressure vessel;  at least two circulating blowers which are disposed on the cover of the vessel, which are connected with the heat utilization system, and which function in the direction of flow of the cooling gas;  a first means for shutting down the reactor having an upper portion laterally disposed to the retracted upper section externally to the pressure vessel and a lower portion located within the main body of the pressure vessel; and  a second means for shutting down the reactor having an upper portion laterally disposed to the upper retracted section externally to the pressure vessel and a lower portion located within the main body of the pressure vessel;  wherein said first means for shutting down the reactor comprises a plurality of absorber rods, bores in said side section of said reflectors which function to contain said absorber rods, and rod drives disposed outside of said steel pressure vessel in the area of said retracted upper section, said rod drives functioning to insert the rods into the bores.  wherein said said second means for shutting down the reactor comprises small absorber spheres, a plurality of storage containers disposed outside the steel pressure vessel in the area of the retracted upper section, for containing the small absorber spheres, annular conduits connected to said storage containers which are arranged inside the steel pressure vessel, projections on said side of said reflector which protrude into the core; and channels in said projections which are connected to said annular conduits and which serve to introduce the small absorber spheres.  a high-temperature pebble bed reactor having a core of spherical fuel elements and a reflector which surrounds the core and which has a side section;  a multicomponent cylindrical steel pressure vessel surrounding said reactor including a retracted upper section, a cover and a main body;  a heat utilization system positioned in the retracted section of the pressure vessel, comprising only one steam generator with a centrally located sub-system and at least one annular sub-system independent from said centrally located sub-system wherein said annular sub-system surrounds said centrally located sub-system and wherein said heat utilization system uses a cooling gas which flows from bottom to top through the core and the pressure vessel;  at least two circulating blowers which are disposed on the cover of the vessel, which are connected with the heat utilization system, and which function in the direction of flow of the cooling gas;  a first means for shutting down the reactor; and  a second means for shutting down the reactor.  a plurality of absorber rods;  bores in said side section of said reflectors which function to contain said absorber rods; and  rod drives disposed outside of said steel pressure vessel in the area of said retracted upper section, said rod drives functioning to insert the rods into the bores.  small absorber spheres;  a plurality of storage containers disposed outside the steel pressure vessel into the area of the retracted upper section, for containing the small absorber spheres;  annular conduits connected to said storage containers which are arranged inside the steel pressure vessel;  projections on said side of said reflector which protrude into the core; and  channels in said projections which are connected to said annular conduits and which serve to introduce the small absorber spheres.  housings for the rod drives of the first means for shutting down;  fittings in the region between the main body of the steel pressure vessel and the retracted upper section for fastening the housings to the steel pressure vessel; and  flange means for attaching said housings to said fittings.  fittings in the region between the main body of the steel pressure vessel and the retracted upper section for fastening the housings to the steel pressure vessel, wherein said housings are welded to said fittings.  fittings on the cover of the steel pressure vessel for fastening the circulating blowers; and  flange means on the circulating blowers for attaching the blowers to said fittings.  a support base for said core;  at least one outlet means for removing fuel elements from the core; and  decollating means provided for said outlet means for isolating the fuel elements.  a thermal side shield upon which said side section of said reflector rests; and  raised support points on said thermal side shield which create gaps for the passage of cooling gas. 2. A nuclear power installation of claim 1, 3. A nuclear power installation, comprising: 4. A nuclear power installation as claimed in claim 3, wherein each independent sub-system comprises a distributor, a collector, an inlet line, and an outlet line. 5. A nuclear power plant according to claim 3, wherein the first means for shutting down the reactor comprises: 6. A nuclear power plant according to claim 5, wherein the second means for shutting down the reactor comprises: 7. A nuclear power palnt according to claim 6, wherein said rod drives are means for gravitational introduction of the absorber rods of the first shut-down arrangement and said first means for shutting down comprises means for rapid shut-down (scram) of the high-temperature pebble bed reactor, and wherein the second shut-down arrangement may optionally be used for said rapid shut-down. 8. A nuclear power plant according to claim 6, wherein the second means for shutting down the reactor is a means for long-term shut-down of the high-temperature pebble bed reactor. 9. A nuclear power plant according to claim 5, further comprising: 10. A nuclear power plant according to claim 5, further comprising housings for the rod drives of the first means for shutting down the reactor; and 11. A nuclear power plant according to claim 3, further comprising: 12. A nuclear power plant according to claim 3, wherein said heat utilization system further comprises means for removal of residual heat. 13. A nuclear power plant according to claim 12, wherein said circulating blowers cooperate with said heat utilization system for both steam generation and removal of residual heat. 14. A nuclear power plant according to claim 13, wherein one circulating blower is provided for each sub-system of said heat utilization system during both steam generation and removal of residual heat. 15. A nuclear power plant according to claim 12, further comprising a secondary cooling system with a plurality of components for recooling said heat utilization system during the removal of residual heat. 16. A nuclear power plant according to claim 12, further comprising a secondary cooling system for recooling each sub-system of said heat utilization system during the removal of residual heat. 17. A nuclear power plant according to claim 3, wherein said spherical fuel elements pass through the core only once, and wherein the nuclear power plant further comprises: 18. A nuclear power plant according to claim 3, further comprising: 19. A nuclear power plant according to claim 18, further comprising grooves on the side of said side section of said reflector for engaging said support points. 20. A nuclear power plant according to claim 18, wherein said support points are welded to said thermal side shield, and further comprising means for compensating for assembly tolerances. 21. A nuclear power plant according to claim 19, wherein said support points are screwed to said thermal side shield, and further comprising means for compensating for assembly tolerances.