Patent Number: 050376071
Section: claims

1. A structural component for constituting a reactor core, comprising: one and the other metallic members arranged adjacent to each other in a reactor, and  reduction means for reducing a difference swelling between said metallic members due to neutron irradiation thereto,  wherein said one metallic member is at least one of a metallic cladding tube and a tubular member enclosing a plurality of said cladding tubes therein and said other metallic member is a tubular member adjacent said one metallic member and enclosing a plurality of said cladding tubes therein, said reduction means for reducing a difference in swelling between said one and said other metallic members due to neutron irradiation thereto simultaneously enabling reduction of both interaction between said cladding tubes and said tubular member enclosing said cladding tubes therein and interaction between adjacent said tubular members.  one and the other metallic members arranged adjacent to each other in a reactor, and  reduction means for reducing a difference in swelling between said metallic members due to neutron irradiation thereto,  wherein said one metallic member comprises a metallic cladding tube within which substance heated by the neutron irradiation thereto is filled, and said other metallic member comprises a tubular member enclosing a plurality of said cladding tubes therein, and said reduction means comprise solid or hollow coolant refusing members arranged in coolant flowing paths positioned between said tubular member and said cladding tubes adjacent said tubular member, and  wherein said solid or hollow refusing members are arranged only adjacent said tubular member so as to decrease a total area of coolant paths adjacent said tubular member and to reduce the flow rate of coolant thereat and thereby provide an increase in temperature of the tubular member. 2. A structural component for constituting a reactor core, according to claim 1, wherein said reduction means comprise means for relatively reducing the swelling of both of said metallic members. 3. A structural component for constituting a reactor core, according to claim 2, wherein said one metallic member comprises a metallic cladding tube within which substance heated by the neutron irradiation thereto is filled, and said other metallic member comprises a tubular member enclosing a plurality of said cladding tubes therein, and said reduction means are constituted by material of said tubular member having an irradiation temperature where the swelling rate of the material due to the neutron irradiation becomes maximum and that differs from that of material of said cladding tube. 4. A structural component for constituting a reactor core, according to claim 3, wherein said cladding tube is made of such a material that an irradiation temperature where the swelling rate of said material due to the neutron irradiation thereto becomes maximum is lower than said irradiation temperature where the swelling rate of the material of said tubular member due to the neutron irradiation thereto becomes maximum. 5. A structural component for constituting a reactor core, according to claim 3, wherein the material of said cladding tube comprises a steel to which austenite stabilizing elements are added, and the material of said tubular member comprises a steel to which stabilizing elements are not added. 6. A structural component for constituting a reactor core, according to claim 3, wherein the material of said cladding tube comprises ferrite steel, and the material of said tubular member comprises austenite steel. 7. A structural component for constituting a reactor core, according to claim 3, wherein other structure made of material similar to that of either of said cladding tube or said tubular member is arranged between said cladding tube and said tubular member. 8. A structural component for constituting a reactor core, according to claim 1, wherein said one metallic member comprises a metallic cladding tube within which substance heated by the neutron irradiation thereto is filled, and said other metallic member comprises a tubular member enclosing a plurality of said cladding tubes therein, and said reduction means comprise solid or hollow coolant refusing members arranged in coolant flowing paths positioned between said tubular member and said cladding tubes adjacent said tubular member. 9. A structural component for constituting a reactor core, according to claim 8, wherein said cladding tube and said tubular member are made of materials of the same kind. 10. A structural component for constituting a reactor core, according to claim 1, wherein said one metallic member comprises a metallic cladding tube within which nuclear fuel material comprising fissile material and fertile material as substance heated by the neutron irradiation thereto is filled, and said other metallic member comprises a tubular member enclosing a plurality of said cladding tubes therein. 11. A structural component for constituting a reactor core, according to claim 10, wherein said reduction means are constituted by material of said tubular member having an irradiation temperature where the swelling rate of the material due to the neutron irradiation becomes maximum and that differs from that of material of said cladding tube. 12. A structural component for constituting a reactor core, according to claim 10, wherein said reduction means comprise to increase enrichment of the fissile material filled within said cladding tubes adjacent said tubular member more than that of the fissile material filled within said cladding tubes positioned not adjacent said tubular member. 13. A structural component for constituting a reactor core, according to claim 12, wherein said cladding tube and said tubular member are made of materials of the same kind. 14. A structural component for constituting a reactor core, according to claim 1, wherein said one metallic member comprises a metallic cladding tube within which nuclear fission reaction controlling material comprising neutron absorbing material as substance heated by the neutron irradiation thereto is filled, and said other metallic member comprises a tubular member enclosing a plurality of said cladding tubes therein. 15. A structural component for constituting a reactor core, according to claim 14, wherein said reduction means are constituted by material of said tubular member having an irradiation temperature where the swelling rate of the material due to the neutron irradiation becomes maximum and that differs from that of material of said cladding tube. 16. A structural component for constituting a reactor core, according to claim 14, wherein a guide tube made of material having an irradiation temperature where the swelling rate of the material due to the neutron irradiation becomes maximum and that is higher than that of material of said cladding tube is arranged around said tubular member. 17. A core or a reactor, comprising a plurality of said structural component according to any one of claims 1 to 16 at least. 18. A structural component for constituting a reactor core, comprising: 19. A structural component for constituting a reactor core according to claim 12, wherein said cladding tubes adjacent said tubular member having an increased enrichment of the fissile material with respect to the enrichment of the fissile material filled within said cladding tubes positioned non-adjacent said tubular member so as to enable an increase in temperature of coolant flowing in coolant paths adjacent said tubular member and therewith an increase in the temperature of said tubular member. 20. A structural component for constituting a reactor core according to claim 14, wherein said one metallic member and said other metallic member form a control rod arranged for movement with respect to said reactor core.