Patent Number: 050341855
Section: claims

1. A control blade for a nuclear reactor, comprising: a plurality of wings each in the form of a generally rectangular plate having a longitudinal axis extending in the longitudinal direction of said control blade, said wings being closed at their widthwise ends to each other so as to form a cross-shaped cross section of said control blade;  an upper end structural member fixed to an upper end of each of said wings inserted into a core of the reactor;  a lower end structural member fixed to a lower end of said wing inserted into the reactor core;  a central connection member connecting said upper end structural member and said lower end structural member so as to support said wing; and  packing means formed in said wing, a neutron absorber being packed in said packing means;  said wing being formed of a diluted alloy obtained by diluting a long-lived neutron absorber of hafnium with a diluent of a substance having zirconium or titanium as a main component and said packing means including a plurality of a neutron absorber housing holes formed in said wing.  a plurality of wings each in the form of a generally rectangular plate having a longitudinal axis extending in the longitudinal direction of said control blade, said wings being closed at their widthwise ends to each other so as to form a cross-shaped cross section of said control blade;  an upper end structural member fixed to an upper end of each of said wings inserted into a core of the reactor;  a lower end structural member fixed to a lower end of said wing inserted into the reactor core;  a central connection member connecting said outer end structural member and said inner end structural member so as to support said wing; and  a space section formed in said wing, a neutron absorber being packed in said space section;  said space section being packed with a neutron absorber at least including hafnium and said space section being divided into a first region on a side of the inserted upper end structural member and a second region on a side of the inserted lower end structural member and adjacent to said first region, on a side of the inserted upper end structural member and a second region on a side of the inserted lower end structural member and adjacent to said first region, said first region includes a high-reactivity-worth region in which a diluted alloy obtained by diluting a long-lived neutron absorber with a diluent mainly composed of zirconium or titanium is packed, a plurality of lateral holes extending in the widthwise direction of said wing being arranged in a row over the region where said long-lived neutron absorber is contained, a neutron absorber different from said long-lived neutron absorber being packed in said lateral holes.  a plurality of wings each in the form of a generally rectangular plate having a longitudinal axis extending in the longitudinal direction of said control blade, said wings being closed at their widthwise ends to each other so as to form a cross-shaped cross section of said control blade;  an upper end structural member fixed to an upper end of each of said wings inserted into a core of the reactor;  a lower end structural member fixed to a lower end of said wing inserted into the reactor core;  a central connection member connecting said upper end structural member and said lower end structural member so as to support said wing; and  a space section formed in said wing;  said space section being packed with a neutron absorber at least including hafnium and said neutron absorber packing section including a plurality of neutron absorber housing holes arranged in a row and each extending in a widthwise direction of said wing; said neutron absorber packing space section being divided into a first region on a side of an inserted upper end of said upper structural member where a neutron irradiation rate is particularly high, a second region next to said first region, where subcriticality becomes smaller during shut-down of the reactor, and a third region bordering said second region on the side of a lower rend of said lower end structural member, a long-lived neutron absorber being packed in a first plurality of said housing holes formed in said first region, a neutron absorber such as boron carbide being packed in a second plurality of said housing holes formed in said second and third regions, at least one of said housing holes formed in said third region being formed as a gas plenum.  a plurality of wings each in the form of a generally rectangular plate having an longitudinal axis extending in the longitudinal direction of said control blade, said wings being closed at their widthwise ends to each other so as to form a cross-shaped cross section of said control blade;  an upper end structural member fixed to an upper end of each of said wings inserted into a core of the reactor;  a lower end structural member fixed to a lower end of said wing inserted into the reactor core; and  a central connection member connecting said upper end structural member and said lower end structural member so as to support said wing;  a metallic sheath member having a generally U-shaped cross section being secured in each of said wings; said wing being divided into a first section on the side of an upper end of said upper end structural member and a second region on the side of a lower end of said lower end structural member and adjacent to said first region; a long-lived neutron absorber is housed in said sheath within said first region; said first region including a high-reactivity-worth region; a plurality of aligned holes being formed in said long-lived neutron absorber within said high-reactivity-worth region; and  a neutron absorber element different from hafnium being packed in said holes. 2. A control blade for a nuclear reactor according to claim 1, wherein hafnium content of said diluted alloy forming said wing is constant through an overall length of said wing in the axial direction of said control blade, said content being set to 20 to 90% by weight. 3. A control blade for a nuclear reactor according to claim 1, wherein said diluted alloy forming said wing is formed in such a manner that the hafnium content gradually decreases generally from the inserted upper end of said wing toward the inserted lower end of the same. 4. A control blade for a nuclear reactor according to claim 1, wherein the neutron absorber housing holes are arranged through the overall length of said wing in the longitudinal direction of the same. 5. A control blade for a nuclear reactor according to claim 1, wherein said neutron absorber housing holes extend in the longitudinal direction of said wing. 6. A control blade for a nuclear reactor according to claim 1, wherein said neutron absorber housing holes extend in a widthwise direction of said wing. 7. A control blade for a nuclear reactor according to claim 6, wherein said neutron absorber housing holes have substantially the same cross-sectional area, and different neutron absorbers including a gas plenum, selected with respect to the neutron irradiation rate are packed in said neutron housing holes. 8. A control blade for a nuclear reactor according to claim 6, wherein at least one of said neutron absorber housing holes disposed in a region where the subcriticality becomes smaller during shut-down of the reactor is formed as an elongated hole having a cross section elongated in the longitudinal direction of said wing, a neutron absorber which does not swell by neutron absorption reaction is packed in extreme end portions of an internal space of said elongated housing hole closer to the adjacent holes while a neutron absorber containing boron is packed in the rest of said internal space. 9. A control blade for a nuclear reactor according to claim 6, wherein at least one of said neutron absorber housing holes disposed in a region where the subcriticality becomes smaller during shut-down of the reactor is formed as a hole elongated in the longitudinal direction of said wing, a total thickness of metallic wing wall portions on said housing hole is increased at extreme end portions of said elongated housing hole closer to adjacent holes relative to the thickness of said wing wall at an intermediate portion of said elongated hole. 10. A control blade for a nuclear reactor according to claim 6, wherein at least one of said neutron absorber housing holes disposed in a region where the subcriticality becomes smaller during shut-down of the reactor is formed as a hole elongated in the longitudinal direction of said wing, a pair of inner tubes filled with an neutron absorber are fitted in extreme end portions of the internal space of said elongated housing hole closer to the adjacent holes, and a neutron absorber containing boron is packed in the rest of said internal space. 11. A control blade for a nuclear reactor according to claim 6, wherein at least one of said neutron absorber housing holes disposed in a region where the subcriticality becomes smaller during shut-down of the reactor is formed as a hole elongated in the longitudinal direction of said wing, an inner sleeve filled with a neutron absorber containing boron is housed in said elongated housing hole. 12. A control blade for a nuclear reactor according to claim 6, wherein at least one of said neutron absorber housing holes disposed in a region where the subcriticality becomes smaller during shut-down of the reactor is formed as a hole elongated in the longitudinal direction of said wing, swelling absorption dimples are formed in side surfaces of a metallic member constituting said wing at positions of said elongated housing hole. 13. A control blade for a nuclear reactor according to claim 1, wherein said neutron absorber housing holes include holes formed in a lengthwise upper portion of said wing so as to extend in the widthwise direction of said wing, and other holes formed in an lengthwise lower portion of said wing so as to extend in the longitudinal direction of said wing. 14. A control blade for a nuclear reactor according to claim 1, wherein each of said wings is packed with a sheath member having a generally U-shaped cross-section. 15. A control blade for a nuclear reactor, comprising: 16. A control blade for a nuclear reactor according to claim 15, wherein said high-reactivity-worth region formed in said first region has a length of substantially 1/4 of a length of said neutron absorber packing space in the longitudinal direction of said wing, said high-reactivity-worth region is divided into a high-reactivity-worth long-lived region on the side of the inserted upper end and a high-reactivity-worth region on the side of the inserted lower end, and a density of said long-lived neutron absorber contained in said diluted alloy packed in said first region is changed so as to decrease from the side of the inserted upper end toward the inserted lower end. 17. A control blade for a nuclear reactor according to claim 15, wherein said first region has a length of at least 1/4 of the length of said neutron absorber packing space in the longitudinal direction of said wing; a long-lived neutron absorber diluted alloy is housed in said first region; lateral holes extending in the widthwise direction of said wing are formed in said diluted alloy so as to be arranged in a row; at least one of said lateral holes in vicinity of the inserted upper end is formed as a gas plenum; at least one of said lateral holes positioned next to said lateral hole formed as said gas plenum on the side of the inserted lower end is filled with a long-lived neutron absorber; some of said lateral holes which are positioned next to said hole filled with said long-lived neutron absorber on the side of the inserted lower end and which are located in a region where the subcriticality becomes smaller during shut-down of the rector are formed with reduced pitches and are filled with a neutron absorber such as boron carbide; and at least one of said lateral holes located at the end of said first region is filled with a neutron absorber. 18. A control blade for a nuclear reactor according to claim 17, wherein at least one of said neutron absorber housing holes disposed in a region where the subcriticality becomes smaller during shut-down of the reactor is formed as an elongated hole having a cross section elongated in the longitudinal direction of said wing, a neutron absorber which does not swell by neutron absorption reaction is packed in extreme end portions of the internal space of said elongated housing hole closer to the adjacent holes while a neutron absorber containing boron is packed in the rest of said internal space. 19. A control blade for a nuclear reactor according to claim 17, wherein at least one of said neutron absorber housing holes disposed in a region where the subcriticality becomes smaller during shut-down of the reactor is formed as a hole elongated in the longitudinal direction of said wing, a total thickness of metallic wing wall portions on said housing hole is increased at extreme end portions of said elongated housing hole closer to the adjacent holes relative to the thickness of said wing wall at an intermediate portion of said elongated hole. 20. A control blade for a nuclear reactor according to claim 17, wherein at least one of said neutron absorber housing holes disposed in a region where the subcriticality becomes smaller during shut-down of the reactor is formed as a hole elongated in the longitudinal direction of said wing, a pair of inner tubes filled with an neutron absorber are fitted in extreme end portions of the internal space of said elongated housing hole closer to the adjacent holes, and a neutron absorber containing boron is packed in the rest of said internal space. 21. A control blade for a nuclear reactor according to claim 17, wherein at least one of said neutron absorber housing holes disposed in a region where the subcriticality becomes smaller during shut-down of the reactor is formed as a hole elongated in the longitudinal direction of said wing, an inner sleeve filled with a neutron absorber containing boron is housed in said elongated housing hole. 22. A control blade for a nuclear reactor according to claim 17, wherein at least one of said neutron absorber housing holes disposed in a region where the subcriticality becomes smaller during shut-down of the reactor is formed as a hole elongated in the longitudinal direction of said wing, swelling absorption dimples are formed in side surfaces of a metallic member constituting said wing at positions of said elongated housing hole. 23. A control blade for a nuclear reactor according to claim 17, wherein neutron absorber rods filled with a neutron absorber such as boron carbide are arranged in said second region next to said first region on the side of said inserted lower end. 24. A control blade for a nuclear reactor according to claim 15, wherein neutron absorber rods filled with a neutron absorber such as boron carbide are arranged in said second region next to said first region on the side of the inserted lower end. 25. A control blade for a nuclear reactor according to claim 15, wherein said second region includes a diluted alloy section formed by diluting a long-lived neutron absorber with a diluent; a plurality of lateral holes extending in the widthwise direction of said wing are formed in said diluted alloy section; and a neutron absorber is housed in said lateral holes. 26. A control blade for a nuclear reactor according to claim 15, wherein a composite neutron absorber formed by packing a high-reactivity-worth substance in a diluted alloy obtained by diluting a long-lived neutron absorber such as hafnium with a diluent such as zirconium or titanium is disposed in a portion of said neutron absorber packing space section where the subcriticality becomes smaller from the inserted upper end toward the inserted lower end during shut-down of the reactor. 27. A control blade for a nuclear reactor according to claim 26, wherein said high-reactivity-worth substance includes boron carbide, europium oxide and europium hexaboride. 28. A control blade for a nuclear reactor according to claim 15, wherein a long-lived neutron absorber is disposed in at least one of said lateral housing holes formed in an inserted upper end region of each of said wing corresponding to said neutron absorber packing space section, and some of said housing holes formed in a region where the subcriticality becomes smaller during shut-down of the reactor have a cross-sectional area larger than that of the housing holes disposed in the other regions. 29. A control blade for a nuclear reactor according to claim 15, wherein said first region extends from the inserted upper end of said wing in the longitudinal direction of the same through a distance of 1/4 to 3/4 of an overall axial length of the reactor core; a pair of opposed neutron absorber plates are disposed in said second region so as to be spaced apart from each other in the direction of thickness of said wing to form a gap through which cooling water can flow. 30. A control blade for a nuclear reactor according to claim 15, wherein a neutron absorber is housed in said second region; said neutron absorber includes a diluted alloy obtained by diluting hafnium provided as a long-lived neutron absorber with zirconium provided as a diluent; and content of hafnium in said diluted alloy is equal to or lower than about 2% by weight. 31. A control blade for a nuclear reactor according to claim 15, wherein a neutron absorber is housed in said first and second regions; said neutron absorber includes a diluted alloy obtained by diluting hafnium provided as a long-lived neutron absorber with zirconium provided as a diluent; and content of hafnium in said diluted alloy is equal to or lower than about 10% by weight. 32. A control blade for a nuclear reactor according to claim 15, wherein a neutron absorber is housed in said first and second regions; said neutron absorber includes a diluted alloy obtained by diluting hafnium provided as a long-lived neutron absorber with titanium provided as a diluent; and content of hafnium in said diluted alloy is equal to or lower than about 30% by weight. 33. A control blade for a nuclear reactor according to claim 15, wherein each of said wing is packed with a sheath member having a generally U-shaped cross section. 34. A control blade for a nuclear reactor according to claim 33, wherein said sheath member is formed from a diluted alloy obtained by diluting hafnium provided as a long-lived neutron absorber with zirconium provided as a diluent; and content of hafnium in said diluted alloy is set to about 20% by weight. 35. A control blade for a nuclear reactor according to claim 33, wherein said sheath member is formed from a diluted alloy obtained by diluting hafnium provided as a long-lived neutron absorber with titanium provided as a diluent; and content of hafnium in said diluted alloy is set to about 30% by weight. 36. A control blade for a nuclear reactor of the type comprising: 37. A control blade for a nuclear reactor according to claim 36, wherein a sectional area of said neutron absorber housing hole formed in said second region is larger than that of the housing holes formed in the other regions. 38. A control blade for a nuclear reactor according to claim 32, wherein at least one of said neutron absorber housing holes disposed in a region where the subcriticality becomes smaller during shut-down of the reactor is formed as an elongated hole having a cross section elongated in the longitudinal direction of said wing, a neutron absorber which does not swell by neutron absorption reaction is packed in extreme end portions of the internal space of said elongated housing hole closer to the adjacent holes while a neutron absorber containing boron is packed in the rest of said internal space. 39. A control blade for a nuclear reactor according to claim 37, wherein at least one of said neutron absorber housing holes disposed in a region where the subcriticality becomes smaller during shut-down of the reactor is formed as a hole elongated in the longitudinal direction of said wing, a total thickness of metallic wing wall portions on said housing hole is increased at extreme end portions of said elongated housing hole closer to the adjacent holes relative to the thickness of said wing plate at an intermediate portion of said elongated hole. 40. A control blade for a nuclear reactor according to claim 36, wherein each of said wing is packed with a sheath member having a generally U-shaped cross section. 41. A control blade for a nuclear reactor according to claim 36, wherein at least one of said neutron absorber housing holes disposed in a region where the subcriticality becomes smaller during shut-down of the reactor is formed as a hole elongated in the longitudinal direction of said wing, a pair of inner tubes filled with an neutron absorber are fitted in extreme end portions of an internal space of said elongated housing hole closer to the adjacent holes, and a neutron absorber containing boron is packed in the rest of said internal space. 42. A control blade for a nuclear reactor according to claim 36, wherein at least one of said neutron absorber housing holes disposed in a region where the subcriticality becomes smaller during shut-down of the reactor is formed as a hole elongated in the longitudinal direction of said wing, an inner sleeve filled with a neutron absorber containing boron is housed in said elongated housing hole. 43. A control blade for a nuclear reactor according to claim 36, wherein at least one of said neutron absorber housing holes disposed in a region where the subcriticality becomes smaller during shut-down of the reactor is formed as a hole elongated in the longitudinal direction of said wing, swelling absorption dimples are formed in side surfaces of a metallic member constituting said wing at positions of said elongated housing hole. 44. A control blade for a nuclear reactor, comprising: