摘要
核能系统小型化是核能未来发展的重要方向,其中小型铅冷快堆是技术路线之一。在小型铅冷快堆研发过程中,瞬态工况下热工水力安全特性是重要的研究内容之一,这不仅是对反应堆安全特性的重要验证,也对反应堆系统的后续设计完善具有重要参考价值。兆瓦级铅冷快堆SMILE是国家电投集团科学技术研究院有限公司提出的高安全、紧凑型铅冷快堆方案。为研究SMILE的安全特性,使用系统分析程序ATHLET对其进行典型无保护瞬态热工水力性能分析。结果表明,SMILE在应对典型无保护瞬态事故时具备良好的固有安全特性。
Miniaturization of nuclear energy systems will be a promising direction for nuclear industry development in the future,in which micro lead-cooled fast reactors(LFRs)are a type of technical route in relevant.During the R&D of micro LFRs,transient thermal-hydraulic safety analysis is one of the important research fields,which can not only verify the safety of the design,but also provide optimization reference for the follow-up design of the reactor.SMILE is a megawatt-level micro LFR with high safety and compactness,designed by State Power Investment Corporation Research Institute.For SMILE,pure lead is applied as the coolant.The fuel adopts UO_(2),while the cladding and structural materials use independently developed wide oxygen-controlling corrosion-resistant materials,which can simplify or even omit complex oxygen measurement and control systems.Its core is designed for long-life without refueling,eliminating complex refueling devices.Its reactivity is controlled by external drums.The main system employs a compact design scheme,using a pool-type integrated compact layout,with an integrated main pump and main heat exchanger structure.The secondary system uses a compact water steam cycle or S-CO_(2) Brayton cycle,along with a non-passive residual heat removal system.Due to the advanced concepts of lead-cooled fast reactor designs,there has not been a mature unified thermal-hydraulic safety criterion.Based on SMILE’s design characteristics and a literature review,some key parameters’performance criteria for thermal-hydraulic safety are proposed,including flow velocity of the coolant,coolant temperature,temperature of the fuel cladding,etc.During reactor operation,various abnormal events deviating from normal operating ranges may occur,potentially leading to accident conditions.For SMILE,unprotected loss of flow(ULOF),unprotected transient over-power(UTOP),unprotected loss of heat sink(ULOHS),were deeply investigated in the present paper.ATHLET(analysis of thermal-hydraulics of leaks and transients)is a best-estimate one-dimensional system safety analysis program developed by Gesellschaft für Anlagen-und Reaktorsicherheit(GRS),which is applicable to analyzing various reactor types such as pressurized water reactors,boiling water reactors,graphite-water-cooled reactors,and CANDU reactors,for both benchmark and beyond-benchmark accident analyses.With the development of Gen-Ⅳnuclear energy systems,GRS has extended the applicability of ATHLET,incorporating properties of metals and liquid metal heat transfer relationships,enabling to be applied for analyzing the thermal-hydraulic characteristics of lead-cooled fast reactors.Through analysis,it is found that under normal conditions,the results obtained from ATHLET are in good agreement with the design values,thus AHTLET program is capable of analyzing the transient features of SMILE.Under typical unprotected transient accident conditions,SMILE shows a good natural circulation performance and thermal characteristics,in particular given it inherent safety features.However,according to simulation results,in the event of an ULOF transient accident,the cladding temperature of the fuel exceeds the maximum temperature limit,which could potentially threaten the reactor’s safe operation.Therefore,in the future high-temperature corrosion-resistant materials will be developed,for eliminating or mitigating its impact on the system’s safe operation.
作者
柳春源
肖骏
陈笑松
孙培栋
邢勉
LIU Chunyuan;XIAO Jun;CHEN Xiaosong;SUN Peidong;XING Mian(State Power Investment Corporation Research Institute,Beijing 102209,China;Sun Yat-Sen University,Guangzhou 510275,China)
出处
《原子能科学技术》
EI
CAS
CSCD
北大核心
2024年第4期814-824,共11页
Atomic Energy Science and Technology
基金
国家自然科学基金重大仪器专项(51827810)
国家电投集团科学技术研究院有限公司项目(C-HN-202202)。
关键词
铅冷微堆
系统分析程序
瞬态热工安全分析
micro lead-cooled fast reactor
system analysis program
transient thermal-hydraulic safety analysis