科技报告详细信息
Deep Burn Fuel Cycle Integration: Evaluation of Two-Tier Scenarios
Bays, S. ; Zhang, H. ; Pope, M.
Idaho National Laboratory
关键词: Deep Burn - Modular Helium Reactor;    Reprocessing;    Capacity;    Reactor Physics;    Supply And Demand Advanced Recycling Reactor;   
DOI  :  10.2172/961929
RP-ID  :  INL/EXT-09-15915
RP-ID  :  DE-AC07-99ID-13727
RP-ID  :  961929
美国|英语
来源: UNT Digital Library
PDF
【 摘 要 】

The use of a deep burn strategy using VHTRs (or DB-MHR), as a means of burning transuranics produced by LWRs, was compared to performing this task with LWR MOX. The spent DB-MHR fuel was recycled for ultimate final recycle in fast reactors (ARRs). This report summarizes the preliminary findings of the support ratio (in terms of MWth installed) between LWRs, DB-MHRs and ARRs in an equilibrium “two-tier” fuel cycle scenario. Values from literature were used to represent the LWR and DB-MHR isotopic compositions. A reactor physics simulation of the ARR was analyzed to determine the effect that the DB-MHR spent fuel cooling time on the ARR transuranic consumption rate. These results suggest that the cooling time has some but not a significant impact on the ARRs conversion ratio and transuranic consumption rate. This is attributed to fissile worth being derived from non-fissile or “threshold-fissioning” isotopes in the ARR’s fast spectrum. The fraction of installed thermal capacity of each reactor in the DB-MHR 2-tier fuel cycle was compared with that of an equivalent MOX 2-tier fuel cycle, assuming fuel supply and demand are in equilibrium. The use of DB-MHRs in the 1st-tier allows for a 10% increase in the fraction of fleet installed capacity of UO2-fueled LWRs compared to using a MOX 1st-tier. Also, it was found that because the DB-MHR derives more power per unit mass of transuranics charged to the fresh fuel, the “front-end” reprocessing demand is less than MOX. Therefore, more fleet installed capacity of DB-MHR would be required to support a given fleet of UO2 LWRs than would be required of MOX plants. However, the transuranic deep burn achieved by DB-MHRs reduces the number of fast reactors in the 2nd-tier to support the DB-MHRs “back-end” transuranic output than if MOX plants were used. Further analysis of the relative costs of these various types of reactors is required before a comparative study of these options could be considered complete.

【 预 览 】
附件列表
Files Size Format View
961929.pdf 159KB PDF download
  文献评价指标  
  下载次数:11次 浏览次数:19次