| 摘要 |
<p>1,000,780. Reactors. UNITED STATES ATOMIC ENERGY COMMISSION. July 2, 1964 [Oct. 16, 1963], No. 27293/64. Heading G6C. A large, fast fission reactor (output 300 MW(e)) has its fissionable regions separated by barriers, which comprise a moderator region sandwiched between regions which absorb neutrons. The absorbing material is preferably fertile. The invention provides a large, fast reactor having a negative coolant void coefficient, and the reactor described is a direct cycle light-water cooled, super-critical pressure reactor, in which the individual fission regions are sub-critical. The core, Fig. 2, comprises fissile regions 20, 24, fertile regions 21, 23 (and 25) and moderator region 22. The thickness of the moderator region is very small. The core is supported (Fig. 1 ) by suspending its individual components from a top grid plate 44. The fuel elements. Fig. 5, of the various crosssections shown in Fig. 2, each comprise a mass 34 of fissile material in which are embedded nickel alloy tubes 30 containing coolant. The outer tubes 30 are interconnected by nickel alloy strips 32 welded thereto to form the fuel container; end pieces of the same material complete the container. Reading downwards from the top face of a fuel element, it contains the following horizontal layers:- Al 2 O 3 fibres in which gaseous fission products accumulate, insulating ZrO 2 , depleted UO 2 , main fuel charge at the centre, depleted UO 2 , ZrO 2 , and Al 2 O 3 at the bottom. Fig. 5 shows specifically the section of prisms 27, 28 of Fig. 2, which for convenience include a portion 38 of the fertile region 21 or 23 surrounding the moderator. Fuel and fertile material constituents are:- Fuel depleted UO 2 enriched 12¢% PuO 2 UO 2 " 14¢ % " Fertile material " UO 2 " 3¢ % " The depleted UO 2 could be replaced by natural UO 2 using less PuO 2 enrichment. The fertile material is present essentially as a thermal and resonance neutron absorber, and could be replaced by an absorber such as boron. Moderator and control.-Each moderator section 55 comprises a stainless steel tank through which coolant water flows. The tank is internally braced by vertical stainless steel tubes which loosely house safety and control rods of yttrium hydride or zirconium hydride. Coolant circulation.-Light water at supercritical pressure is circulated through the tubes 30 of the prisms 26, 27, 28, 29. The water makes three passes, firstly from top to bottom and bottom to top of prisms 29 and 28, secondly as previous through prisms 27, and thirdly, as before, through prisms 26. Each fuel element has inlet and outlet headers at its top, and a cross-over channel at its bottom. The group of tubes 30 which constitute the downrunner includes those which in part from the fuel element canning which is thus cooled. Ring mains 47-52 (Fig. 1) collect and distribute coolant from and for the various passes, through tubes 53 connected to individual headers. It is contemplated that water passing from the outlet ring main of the second pass will serve as a reheater between stages of a turbine operated by the reactor, before passing to the inlet ring main for the third pass. General.-The invention is also applicable to liquid metal cooled reactors. The reactor described is in a container 46 and cylinder 43, which are filled with helium, which may be bled to remove fission products percolating A1 2 O 3 , fibres in the fuel element ends and thence through the stainless steel end closures. The containers 43, 46 are contained in a water-filled concrete tank 54.</p> |
