NMB4.0: development of integrated nuclear fuel cycle simulator from the front to back-end

IF 0.9 Q3 NUCLEAR SCIENCE & TECHNOLOGY

EPJ Nuclear Sciences & Technologies Pub Date : 2021-01-01 DOI:10.1051/epjn/2021019

T. Okamura, R. Katano, A. Oizumi, K. Nishihara, M. Nakase, H. Asano, K. Takeshita

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引用次数: 3

Abstract

Nuclear Material Balance code version 4.0 (NMB4.0) has been developed through collaborative R&D between TokyoTech&JAEA. Conventional nuclear fuel cycle simulation codes mainly analyze actinides and are specialized for front-end mass balance analysis. However, quantitative back-end simulation has recently become necessary for considering R&D strategies and sustainable nuclear energy utilization. Therefore, NMB4.0 was developed to realize the integrated nuclear fuel cycle simulation from front- to back-end. There are three technical features in NMB4.0: 179 nuclides are tracked, more than any other code, throughout the nuclear fuel cycle; the Okamura explicit method is implemented, which contributes to reducing the numerical cost while maintaining the accuracy of depletion calculations on nuclides with a shorter half-life; and flexibility of back-end simulation is achieved. The main objective of this paper is to show the newly developed functions, made for integrated back-end simulation, and verify NMB4.0 through a benchmark study to show the computational performance.

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NMB4.0:从前端到后端的一体化核燃料循环模拟器开发

核物质平衡代码版本4.0 (NMB4.0)是通过东京科技和日本原子能公司的合作研发开发的。传统的核燃料循环模拟程序主要分析锕系元素，专门用于前端质量平衡分析。然而，定量后端模拟最近成为考虑研发战略和可持续核能利用的必要条件。为此，开发了NMB4.0，实现了从前端到后端的一体化核燃料循环仿真。NMB4.0有三个技术特点:在整个核燃料循环中跟踪179种核素，比任何其他代码都多;采用Okamura显式方法，降低了数值成本，同时保持了半衰期较短的核素耗散计算的准确性;实现了后端仿真的灵活性。本文的主要目的是展示新开发的功能，为集成后端仿真而制作，并通过基准测试研究验证NMB4.0的计算性能。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

EPJ Nuclear Sciences & Technologies NUCLEAR SCIENCE & TECHNOLOGY-

CiteScore

1.00

自引率

20.00%

发文量

审稿时长

10 weeks