Patent Number: 043081010
Section: description

DETAILED DESCRIPTION OF PREFERRED EMBODIMENT In the drawings, 1 designates a pressure vessel in a nuclear reactor and 2 designates a substantially hollow-cylindrical radiation protection device which is made of concrete and which surrounds the pressure vessel 1. The biological shield 2 has a horizontal supporting surface 3 formed from a plurality of metallic bearing plates 4 which are cast integral with the radiation protection. The reactor vessel 1 is supported by a truncated sheet metal cone 5, which is welded to the reactor vessel 1 at its upper end. The lower end of the sheet metal cone is provided with a foot ring 6 welded to it, said foot ring resting against the bearing plates 4. A plurality of blocking members 7 protruding from the supporting surface, which are mainly designed to take up horizontal forces, are arranged to make mechanical contact with radially outwardly facing surfaces of recesses 30 of the foot ring 6, even when the temperature of the foot ring is lower than the temperature at which the temperature increase of the foot ring amounts to 25% of its maximum value, preferably even at room temperature. Two blocking members 7 are welded to each bearing plate 4 and are each run through by a bolt 8 screwed to the member, the lower end of said bolt resting on a plate 23 cast into the concrete and supporting the reactor vessel before the foundation 24 below the bearing plate 4 has been cast. Some of the blocking members are inserted into these recesses with no mentionable clearance, thus giving a locking effect in the tangential direction as well. The biological shield 2 is formed with a plurality of vertical channels 9, each of which is defined by means of a thin-walled lining tube 10. Each channel 9 contains a tensile force transmitting member in the form of a bundle 11 of prestressed steel rods. With their lower ends the steel rods 12 of a bundle 11 are fixed to the lower end of the biological shield 2, and with their upper ends they are fixed to the mid-portion of a yoke 13, which has a radially outer force-transmitting surface 14 making contact with one of the bearing plates 4, and a radially inner force-transmitting surface 15 facing the foot ring 6. Steel wires can be used instead of steel rods. The steel rods 12 are individually attached to a fixing member 16 supported by the yoke 13. The fixing member 16 is surrounded by a casing 17 which, similar to the tube 10, is filled with solidified cement paste 18, which constitutes corrosion protection for the steel rods 12. From the force-transmitting surface 15 of the yoke 13 a compressive force is transmitted to the foot ring via two swivelling castors 19, which include circular-cylindrical contact surfaces 31 arranged in a pressure-transmitting connection with plane surfaces of the yoke 13 and the foot ring 6. In FIG. 2 the axis of rotation of the swivelling castor is perpendicular to the paper plane. The truncated sheet metal cone 5 is provided at its lower end with a circular cooling channel 20, by means of which it is prevented that the temperature of the foot ring becomes so high that the concrete in the radiation protection device may become damaged, and also that the temperature expansion forces from the foot ring and the sheet metal cone becomes too high. When the reactor vessel is hot, the sheet metal cone 5 and the foot ring 6 tend to expand. Since thermal expansion of the foot ring is prevented by means of the blocking members 7, the heating results in the inner edge of the foot ring 6 being lifted somewhat from the bearing plates 4. The lower side of the foot ring is turned off in such a way that it forms a curved surface extending from points exactly below the swivelling castor 19 and approximately halfway to the outer edge of the foot ring, where the curved surface changes into a plane surface which limits a gap 21 between the foot ring 6 and the bearing plate 4. This means that the shown cross section of the foot ring, upon said lifting at the inner edge, turns about a narrow bearing zone located in the above-mentioned curved surface exactly below the swivelling castor 19. The deformations that take place at varying temperature of the sheet metal cone 5 are thus not counteracted, or only to a minor degree, by the tensioning force which is transmitted to the foot ring 6 via the yoke 13 and the swivelling castor 19, and for the same reason a lifting of the inner edge of the foot ring may take place without causing any mentionable lifting of the yoke 13. The yoke 13 is locked in the radial direction by means of four guiding protrusions 22, which are welded to a corresponding bearing plate 4. The fact that the only mechanical connection between the yoke 13 and the foot ring 6 consists of swivelling castors means that no horizontal force component can be transmitted from the foot ring 6 to the yoke 13. By avoiding a radial movement of the yoke there is no risk of cracks arising in the rust-protecting cement enclosure of the bundle 11 by the bundle being subjected to bending stress. Instead of using cement as corrosion protection for the bundle 11, an elastic material, for example plastic, may be used. In that case it is not equally necessary to avoid a horizontal movement of the yoke 13, and the swivelling castor 19 can be replaced with another member transmitting compressive forces.