Patent Number: 046719229
Section: claims

1. A nuclear reactor cooled by a liquid metal comprising: a vessel shaft having a bottom;  a liquid metal-filled cylindrical vessel located within said vessel shaft and having a bottom which rests on the bottom of said vessel shaft;  lower supports between said vessel shaft bottom and said vessel bottom;  a slab sealing off said vessel;  means for externally insulating a lateral wall of said vessel;  a reactor core inside said vessel and cooled by liquid metal;  a diagrid supporting said reactor core;  upper supports between said vessel bottom and said diagrid;  at least one heat exchanger ensuring a transmission to a secondary fluid of heat from hot liquid metal flowing out from said core;  at least one pump providing a forced flow of liquid metal in inner areas of the vessel, comprising said core and said heat exchanger; and  means for cooling the bottom of said vessel to a temperature close to the ambient temperature; said inner areas being entirely located above a given horizontal plane, the height of which above said vessel bottom is at least 1/10 of a diameter of said vessel, thus providing below said plane an extended, thermally stratificated static layer of liquid metal, which submits a lower part of said lateral wall and said upper supports to an extended thermal gradient and therefore to acceptable thermal stresses, and which provides an acceptable limitation of thermal losses in direction of said cooled bottom.  a vessel shaft having a bottom;  a liquid metal-filled vessel located within said vessel shaft and having a bottom which rests on the bottom of said vessel shaft;  lower supports between said vessel shaft bottom and said vessel bottom;  a slab sealing off said vessel;  means for externally insulating a lateral wall of said vessel;  a reactor core inside said vessel and cooled by liquid metal;  a diagrid and a support member for supporting said reactor core on the bottom of said vessel;  at least one heat exchanger ensuring a transmission to a secondary fluid of heat from hot liquid metal flowing out from said core;  at least one pump providing a forced flow of liquid metal in inner areas of the vessel, comprising said core and said heat exchanger; and means for cooling the bottom of said vessel to a temperature close to the ambient temperature;  a vessel shaft having a bottom;  a liquid metal-filled vessel located within said vessel shaft and having a bottom which rests on the bottom of said vessel shaft by means of supports forming between the said bottoms a space;  a reactor core contained within said vessel;  a sealing slab sealing off said vessel;  at least one heat exchanger ensuring a transmission of heat from said liquid metal to a secondary fluid;  pump means for providing a forced flow of liquid metal between said reactor core and said heat exchanger, said forced flow being entirely located within said vessel above a given height of static liquid metal rising above the bottom of the vessel; and  means for cooling the bottom of the vessel to a temperature close to ambient temperature comprising a cooling fluid circulating in said space; said space being vertically subdivided into a lower space and an upper space by a fairing, the outer periphery of the lower space being supplied with said cooling fluid by means of an intake pipe, the inner periphery of the lower space communicating with the upper space, said cooling fluid being discharged at the outer periphery of the upper space by at least one discharge pipe, the upper space having a smaller height than the lower space. 2. A nuclear reactor cooled by a liquid metal, comprising: 3. A nuclear reactor cooled by a liquid metal, comprising 4. A nuclear reactor according to claim 3, wherein the fairing can be dismantled to enable the vessel bottom to be inspected. 5. A nuclear reactor according to claim 3 or 4, wherein the inner periphery of both the upper and lower spaces is linked by a baffle, which can fill with a liquid metal in the case of a vessel leak in order to form a siphon stopping the circulation of the cooling fluid. 6. A nuclear reactor according to claim 1, wherein the bottom of the vessel rests on the bottom of the vessel shaft by means of supports forming between the said bottoms a space in which circulates a cooling fluid defining the said means for cooling the bottom of the vessel. 7. A nuclear reactor according to claim 6, wherein the bottom of the vessel is substantially conical and rests on the supports by gravity. 8. A nuclear reactor according to claim 6, wherein said space is vertically subdivided into a lower space and an upper space by a fairing, the outer periphery of the lower space being supplied with said cooling fluid by means of an intake pipe, the inner periphery of the lower space communicating with the upper space, said cooling fluid being discharged at the outer periphery of the upper space by at least one discharge pipe, the upper space having a smaller height than the lower space. 9. A nuclear reactor according to claim 8, wherein the fairing can be dismantled to enable the vessel bottom to be inspected. 10. A nuclear reactor according to claim 8, wherein the inner periphery of both the upper and lower spaces is linked by a baffle, which can fill with a liquid metal in the case of a vessel leak in order to form a siphon stopping the circulation of the cooling fluid. 11. A nuclear reactor according to claim 1, wherein said inner areas further comprise said pump and there is provided a collector receiving cooled metal liquid cooled from discharge ports of said heat exchanger, said pump supplying said cooled metal liquid to the reactor core, screens being placed within the collector below said discharge ports of the heat exchanger and substantially level with said given horizontal plane, whereby said collector contains static liquid metal below said screens. 12. A nuclear reactor according to claim 11, wherein the static liquid metal contained in the vessel is cooled by said means for cooling the bottom of the vessel to a temperature such that the lower part of the metal is in a solid state. 13. A nuclear reactor according to any one of claims 1 or 11, wherein thermally insulated inclusions are provided below said given plane and have a thermal conductivity below that of the liquid metal, so as to limit the downward heat flux over said height. 14. A nuclear reactor according to any one of claims 1 or 11, wherein said vessel is connected to the slab by meas of an expansion bellows with bending corrugations. 15. A nuclear reactor according to any one of claims 1 or 11, wherein a skirt surrounds said vessel and rests on the bottom of the vessel shaft so as to support the slab.