多物理耦合分析自动建模软件SuperMC/MCAM5.2设计与实现
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摘要
超级蒙特卡罗核计算仿真软件系统SuperMC是一套通用、智能、多功能的核系统设计与安全分析软件。多物理耦合分析自动建模软件SuperMC/MCAM(multi-physics coupling analysis modeling program)是其中的自动建模模块,其目标是为多物理耦合分析提供精确高效的建模功能。SuperMC/MCAM最新版本SuperMC/MCAM5.2支持SuperMC、MCNP、FLUKA、Geant4、TRIPOLI等多种蒙特卡罗程序计算模型的自动建模,可进行CAD模型与蒙特卡罗计算模型之间的自动双向转换,以及进行各蒙特卡罗程序计算模型之间的相互转换。本文对SuperMC/MCAM5.2的功能及多蒙特卡罗几何正向与反向转换方法进行了介绍,采用国际热核实验堆ITER基准模型对SuperMC/MCAM5.2进行了测试,测试中SuperMC/MCAM5.2生成的各蒙特卡罗模型计算结果一致,证明了SuperMC/MCAM5.2建模功能的正确性和有效性。
The SuperMC is a general purpose,intelligent and multi-functional program for the design and safety analysis of nuclear systems.The SuperMC/MCAM(multiphysics coupling analysis modeling program)is the advanced modeling module of SuperMC aiming to provide accurate and efficient modeling functions for multi-physics simulation.The new version SuperMC/MCAM5.2is capable to convert models between CADmodel and multiple Monte Carlo codes including SuperMC,MCNP,FLUKA,Geant4 and TRIPOLI.The functions and the converting methodology between CAD and multiple Monte Carlo codes were introduced.The new converting functions for SuperMC,FLUKA and Geant4 were tested with the ITER benchmark model.The calculation results on converted Monte Carlo models agree with each other well,which verifies that these functions and methods are correct and efficient.
The SuperMC is a general purpose,intelligent and multi-functional program for the design and safety analysis of nuclear systems.The SuperMC/MCAM(multiphysics coupling analysis modeling program)is the advanced modeling module of SuperMC aiming to provide accurate and efficient modeling functions for multi-physics simulation.The new version SuperMC/MCAM5.2is capable to convert models between CADmodel and multiple Monte Carlo codes including SuperMC,MCNP,FLUKA,Geant4 and TRIPOLI.The functions and the converting methodology between CAD and multiple Monte Carlo codes were introduced.The new converting functions for SuperMC,FLUKA and Geant4 were tested with the ITER benchmark model.The calculation results on converted Monte Carlo models agree with each other well,which verifies that these functions and methods are correct and efficient.
引文
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[4]ABAQUS users’manual[M].France:Simulia Inc.,2006.
[5]WU Y.CAD-based interface programs for fusion neutron transport simulation[J].Fusion Engineering and Design,2009,84(7-11):1 987-1 992.
[6]吴宜灿,李莹,卢磊,等.蒙特卡罗粒子输运计算自动建模程序系统的研究与发展[J].核科学与工程,2006,26(1):20-27.WU Yican,LI Ying,LU Lei,et al.Research and development of the automatic modeling system for Monte Carlo particle transport simulation[J].Chinese Journal of Nuclear Science and Engineering,2006,26(1):20-27(in Chinese).
[7]HU H,WU Y,CHENG M,et al.Benchmarking of SNAM with the ITER 3Dmodel[J].Fusion Engineering and Design,2007,82:2 867-2 871.
[8]吴宜灿,胡丽琴,龙鹏程,等.先进核能软件发展与核信息学实践[M]∥中国科研信息化蓝皮书.北京:科学出版社,2013:232-244.
[9]WU Y,SONG J,ZHENG H,et al.CAD-based Monte Carlo program for integrated simulation of nuclear system SuperMC[J].Annals of Nuclear Energy,doi:10.1016/j.anucene.2014.08.058.
[10]WU Y,FDS Team.Conceptual design activities of FDS series fusion power plants in China[J].Fusion Engineering and Design,2006,81(23-24):2 713-2 718.
[11]WU Y,QIAN J,YU J.The fusion-driven hybrid system and its material selection[J].Journal of Nuclear Materials,2002,307-311:1 629-1 636.
[12]WU Y,FDS Team.Design analysis of the China Dual-Functional Lithium Lead(DFLL)test blanket module in ITER[J].Fusion Engineering and Design,2007,82:1 893-1 903.
[13]CHEN Y,WU Y.Conceptual study on high performance blanket in a spherical Tokamak fusiondriven transmitter[J].Fusion Engineering and Design,2000,49-50:507-512.
[14]吴宜灿,柏云清,宋勇,等.中国铅基研究反应堆概念设计研究[J].核科学与工程,2014,34(2):56-63.WU Yican,BAI Yunqing,SONG Yong,et al.Conceptual design of China Lead-based Research Reactor CLEAR-Ⅰ[J].Nuclear Science and Engineering,2014,34(2):56-63(in Chinese).
[15]LI Y,LU L,DING A,et al.Benchmarking of MCAM 4.0with the ITER 3Dmodel[J].Fusion Engineering and Design,2007,82(15-24):2 861-2 866.
[16]王国忠,党同强,熊健,等.MCAM4.8在ITER建筑大厅中子学建模中的应用[J].核科学与工程,2011,31(4):351-355.WANG Guozhong,DANG Tongqiang,XIONG Jian,et al.Application of MCAM4.8in creating neutronics model for ITER building[J].Chinese Journal of Nuclear Science and Engineering,2011,31(4):351-355(in Chinese).
[17]SONG Jing,SUN Guangyao,CHEN Zhenping,et al.Benchmarking of CAD-based SuperMC with ITER benchmark model[J].Fusion Engineering and Design,2014,89(11):2 499-2 503.
[18]BRIESMEISTER J F.MCNP:A general Monte Carlo N-particle transport code,version 4C,LA-13709-M[M].US:LANL,2000.
[19]FASSO A,FERRARI A,RANFT J,et al.FLUKA:A multi-particle transport code,SLAC-R-773[M].Stanford:Stanford University,2005.
[20]AGOSTINELLI S,ALLISON J,AMAKO K,et al.Geant4:A simulation toolkit[M].Nucl Instrum Methods A,2003,506(3):250-303.
[21]BOTH J P,MAZZOLO A,PENELIAU Y,et al.User manual for version 4.3of the TRIPOLI-4 Monte-Carlo method particle transport computer code[M].France:CEA,2003.
[22]LU L,LEE Y K,ZHANG J,et al.Development of Monte Carlo automatic modeling functions of MCAM for TRIPOLI-ITER application[J].Nucl Instrum Methods A,2009,605(3):384-387.