Patent Number: 044420668
Section: claims

1. A support floor for the core of a high temperature pebble bed nuclear reactor comprising: a plurality of support columns placed directly adjacent one another forming the reactor core floor;  a bed of spherical fuel elements forming the reactor core;  a cylindrical side reflector surrounding said columns and the reactor core;  a thermal side shield arranged at a distance around said cylindrical side reflector to form an annular space; and  means for retaining said support columns in their respective horizontal positions said means disposed in said annular space between the lower part of the side reflector and the thermal side shields to substantially prevent the formation of expansion gaps between said columns. 2. The support floor of claim 1, wherein said support columns have a hexagonal cross section. 3. The support floor of claim 2, wherein each of said support columns rests upon a circular column having a diameter smaller than the bottom surface of said support column and wherein said circular columns rest upon the layered floor of the nuclear reactor. 4. The support floor of claim 1, wherein the nuclear reactor is a high capacity reactor and said retaining means comprise a plurality of spring supports. 5. The support floor of claim 4, wherein said spring supports are arranged so that the gaps developing after an extended operating period of the nuclear reactor between the support columns remain under a predetermined maximum size. 6. The support floor of claim 1, wherein the nuclear reactor is a low capacity reactor and said retaining means comprise a plurality of supporting struts. 7. The support floor of claim 6, wherein the maximum possible differential radial thermal expansion of the support floor and said thermal side shield are arranged to define the clearance on said support struts. 8. The support floor of claim 1, wherein said retaining means comprise a plurality of spring supports as restoring elements, and wherein the restoring force of said spring supports is dimensioned so that the size of the gaps developing between said support columns remains smaller than the diameter of absorber balls added to the core of the reactor. 9. The support floor of claim 1, wherein said side reflector has a plurality of radial gaps. 10. The support floor of claim 3, further comprising a plurality of cooling gas bores arranged in said supporting columns. 11. The support floor of claim 10, wherein said cooling gas bores are in open communication with said core at one end and with a gas collecting space at the other end. 12. The support floor of claim 11, wherein said gas collecting space is defined by said circular columns the overlapping lower ends of said support columns and said reactor floor.