氟盐冷却小型模块化反应堆中使用氢基慢化剂的棱柱形燃料概念的反应堆物理特性评估

IF 0.5 Q4 NUCLEAR SCIENCE & TECHNOLOGY Journal of Nuclear Engineering and Radiation Science Pub Date : 2023-11-01 DOI:10.1115/1.4063388
Huiping Yan, Blair Bromley
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引用次数: 0

摘要

摘要氟盐冷却高温堆(FHR)将高温气冷堆(HTGR)技术的固体燃料和慢化剂设计与熔盐堆(MSR)技术的氟盐冷却剂(liff - bef2, FLiBe)有效地结合在一起,实现了低压(~ 1 atm, 101.325 kPa)和高温(~ 700℃)运行。FHR的设计和运行特点使其成为小型模块化反应堆(SMR)的一个潜在的有吸引力的选择,前提是它可以进行修改,使其在物理上变小,并在足够低的功率水平(<350 MWth/<150 MWel)下运行。大多数FHR-SMR设计使用三结构各向同性(TRISO)燃料颗粒形式的高含量低浓缩铀(HALEU)燃料,并结合使用石墨慢化剂。然而,FHR-SMR的其他设计概念可能会提供更好的性能特征,同时利用可替代的裂变燃料供应选项。在这项探索性研究中,使用Serpent进行了晶格物理计算,以评估FHR-SMR的另一种棱柱形燃料块设计概念,该设计使用涂覆的环形燃料颗粒代替triso颗粒燃料致密体,同时使用由7LiH制成的氢基固体慢化剂棒。在最初的研究中,发现由7LiH制成的120个慢化剂棒的燃料块往往具有较大的正温度反应性系数(TRCs),这是出于安全原因而不希望看到的。然而,将慢化剂棒的数量减少到90或54,同时增加燃料棒和冷却剂孔的数量,导致温度系数低或负。对于采用54-7LiH慢化剂棒的棱柱形燃料块设计,在燃料(F)、石墨(G)、氢(H)和冷却剂(C)温度同时变化的情况下,等温反应性温度系数(等温TRC)的范围在- 0.159 mk/K和- 0.054 mk/K之间,具体取决于工作温度和燃料燃耗。在350兆瓦的反应堆堆芯中,这种替代FHR-SMR燃料使用低浓铀(LEU)燃料可实现单批堆芯寿命~ 10年,使用高浓铀(halu)燃料可实现单批堆芯寿命~ 45年。
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Assessment of Reactor Physics Characteristics of Prismatic Fuel Concepts with a Hydrogen-based Moderator for Use in a Fluoride Salt-Cooled Small Modular Reactor
Abstract Fluoride-salt-cooled high temperature reactor (FHR) effectively combines the solid fuel and moderator design of high-temperature gas-cooled reactor (HTGR) technology with the fluoride salt coolant (LiF-BeF2, FLiBe) of molten salt reactor (MSR) technology, enabling low-pressure (∼1 atm, 101.325 kPa), and high-temperature (∼700 °C) operations. The design and operational features of the FHR make it a potentially attractive option for a small modular reactor (SMR), provided that it can be modified and made physically small and operate at a low-enough power level (&lt;350 MWth/&lt;150 MWel). Most FHR-SMR designs use high-assay low enriched uranium (HALEU) fuel in the form of tri-structural isotropic (TRISO) fuel particles, combined with the use of a graphite moderator. However, there are alternative design concepts for an FHR-SMR that may offer superior performance characteristics, while utilizing an alternative fissile fuel supply option. In this exploratory study, lattice physics calculations were performed with Serpent to evaluate an alternative FHR-SMR prismatic fuel block design concept using coated annular fuel pellets instead of TRISO-particle fuel compacts, along with the use of hydrogen-based solid moderator rods made of 7LiH. In initial studies, it was found that fuel blocks with 120 moderator rods made of 7LiH tended to have large positive temperature reactivity coefficients (TRCs), which is undesirable for safety reasons. However, reducing the number of moderator rods to 90 or 54, while increasing the number of fuel rods and coolant holes led to low or negative temperature coefficients. For a prismatic fuel block design with 54-7LiH moderator rods, the isothermal temperature coefficient of reactivity (Isothermal TRC), with simultaneous changes in the fuel (F), graphite (G), hydrogen (H), and coolant (C) temperatures, ranges between −0.159 mk/K and −0.054 mk/K, depending on the operating temperature and fuel burnup. Such alternative FHR-SMR fuels could achieve a single-batch core life of ∼10 years with low enriched uranium (LEU) fuel, and ∼45 years with HALEU, in a 350-MWth reactor core.
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期刊介绍: The Journal of Nuclear Engineering and Radiation Science is ASME’s latest title within the energy sector. The publication is for specialists in the nuclear/power engineering areas of industry, academia, and government.
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