Development of virtual reality-based simulation system for nuclear and radiation safety

Yi Can Wu; Tao He; Li Qin Hu; Peng Cheng Long; Lei Ming Shang; Shao Heng Zhou; Qi Yang; Jin Bo Zhao; Shu Zhang; Zi Hui Yang; Ting Li; Xiang Cheng; Jing Wang; Jie Wang; Jing Song; Meng Yun Cheng; Sheng Peng Yu; Li Juan Hao

doi:10.7538/yzk.2015.49.S0.0007

Development of virtual reality-based simulation system for nuclear and radiation safety

Yi Can Wu
, Tao He
, Li Qin Hu
, Peng Cheng Long
, Lei Ming Shang
, Shao Heng Zhou
, Qi Yang
, Jin Bo Zhao
, Shu Zhang
, Zi Hui Yang
, Ting Li
, Xiang Cheng
, Jing Wang
, Jie Wang
, Jing Song
, Meng Yun Cheng
, Sheng Peng Yu
, Li Juan Hao

School of Energy and Power Engineering

Chinese Academy of Sciences

Research output: Contribution to journal › Article › peer-review

5 Scopus citations

Abstract

How to reduce the radiation dose to worker is one of the focus problems of radiation protection research. Based on digital reactor and radiation virtual human technologies, a virtual reality-based simulation system for nuclear and radiation safety named SuperMC/RVIS2.3 was developed. The basic functions of SuperMC/RVIS2.3 include CAD-based modeling and virtual assembly simulation of complex components, visualized analysis of dynamical 3D radiation dose field coupled with geometry model, virtual roaming simulation and organic dose evaluation in radiation environment. SuperMC/RVIS2.3 was applied in the maintenance simulation of International Thermonuclear Experimental Reactor (ITER) poloidal field (PF) repair and target's maintenance scenario of China LEAd-based Research Reactor (CLEAR-I). The test result shows that the system makes it possible to safely perform work scenario designs and optimization, maintenance plan, emergency evaluation and operation training.

Original language	English
Pages (from-to)	7-15
Number of pages	9
Journal	Yuanzineng Kexue Jishu/Atomic Energy Science and Technology
Volume	49
DOIs	https://doi.org/10.7538/yzk.2015.49.S0.0007
State	Published - 20 May 2015

Keywords

Organic dose assessment
Radiation protection
RVIS
SuperMC
Virtual simulation

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10.7538/yzk.2015.49.S0.0007

Cite this

Wu, Y. C., He, T., Hu, L. Q., Long, P. C., Shang, L. M., Zhou, S. H., Yang, Q., Zhao, J. B., Zhang, S., Yang, Z. H., Li, T., Cheng, X., Wang, J., Wang, J., Song, J., Cheng, M. Y., Yu, S. P., & Hao, L. J. (2015). Development of virtual reality-based simulation system for nuclear and radiation safety. Yuanzineng Kexue Jishu/Atomic Energy Science and Technology, 49, 7-15. https://doi.org/10.7538/yzk.2015.49.S0.0007

@article{342026f33f024acabc6eb199f5fc4f68,

title = "Development of virtual reality-based simulation system for nuclear and radiation safety",

abstract = "How to reduce the radiation dose to worker is one of the focus problems of radiation protection research. Based on digital reactor and radiation virtual human technologies, a virtual reality-based simulation system for nuclear and radiation safety named SuperMC/RVIS2.3 was developed. The basic functions of SuperMC/RVIS2.3 include CAD-based modeling and virtual assembly simulation of complex components, visualized analysis of dynamical 3D radiation dose field coupled with geometry model, virtual roaming simulation and organic dose evaluation in radiation environment. SuperMC/RVIS2.3 was applied in the maintenance simulation of International Thermonuclear Experimental Reactor (ITER) poloidal field (PF) repair and target's maintenance scenario of China LEAd-based Research Reactor (CLEAR-I). The test result shows that the system makes it possible to safely perform work scenario designs and optimization, maintenance plan, emergency evaluation and operation training.",

keywords = "Organic dose assessment, Radiation protection, RVIS, SuperMC, Virtual simulation",

author = "Wu, \{Yi Can\} and Tao He and Hu, \{Li Qin\} and Long, \{Peng Cheng\} and Shang, \{Lei Ming\} and Zhou, \{Shao Heng\} and Qi Yang and Zhao, \{Jin Bo\} and Shu Zhang and Yang, \{Zi Hui\} and Ting Li and Xiang Cheng and Jing Wang and Jie Wang and Jing Song and Cheng, \{Meng Yun\} and Yu, \{Sheng Peng\} and Hao, \{Li Juan\}",

year = "2015",

month = may,

day = "20",

doi = "10.7538/yzk.2015.49.S0.0007",

language = "英语",

volume = "49",

pages = "7--15",

journal = "Yuanzineng Kexue Jishu/Atomic Energy Science and Technology",

issn = "1000-6931",

publisher = "Atomic Energy Press",

}

Wu, YC, He, T, Hu, LQ, Long, PC, Shang, LM, Zhou, SH, Yang, Q, Zhao, JB, Zhang, S, Yang, ZH, Li, T, Cheng, X, Wang, J, Wang, J, Song, J, Cheng, MY, Yu, SP & Hao, LJ 2015, 'Development of virtual reality-based simulation system for nuclear and radiation safety', Yuanzineng Kexue Jishu/Atomic Energy Science and Technology, vol. 49, pp. 7-15. https://doi.org/10.7538/yzk.2015.49.S0.0007

TY - JOUR

T1 - Development of virtual reality-based simulation system for nuclear and radiation safety

AU - Wu, Yi Can

AU - He, Tao

AU - Hu, Li Qin

AU - Long, Peng Cheng

AU - Shang, Lei Ming

AU - Zhou, Shao Heng

AU - Yang, Qi

AU - Zhao, Jin Bo

AU - Zhang, Shu

AU - Yang, Zi Hui

AU - Li, Ting

AU - Cheng, Xiang

AU - Wang, Jing

AU - Wang, Jie

AU - Song, Jing

AU - Cheng, Meng Yun

AU - Yu, Sheng Peng

AU - Hao, Li Juan

PY - 2015/5/20

Y1 - 2015/5/20

N2 - How to reduce the radiation dose to worker is one of the focus problems of radiation protection research. Based on digital reactor and radiation virtual human technologies, a virtual reality-based simulation system for nuclear and radiation safety named SuperMC/RVIS2.3 was developed. The basic functions of SuperMC/RVIS2.3 include CAD-based modeling and virtual assembly simulation of complex components, visualized analysis of dynamical 3D radiation dose field coupled with geometry model, virtual roaming simulation and organic dose evaluation in radiation environment. SuperMC/RVIS2.3 was applied in the maintenance simulation of International Thermonuclear Experimental Reactor (ITER) poloidal field (PF) repair and target's maintenance scenario of China LEAd-based Research Reactor (CLEAR-I). The test result shows that the system makes it possible to safely perform work scenario designs and optimization, maintenance plan, emergency evaluation and operation training.

AB - How to reduce the radiation dose to worker is one of the focus problems of radiation protection research. Based on digital reactor and radiation virtual human technologies, a virtual reality-based simulation system for nuclear and radiation safety named SuperMC/RVIS2.3 was developed. The basic functions of SuperMC/RVIS2.3 include CAD-based modeling and virtual assembly simulation of complex components, visualized analysis of dynamical 3D radiation dose field coupled with geometry model, virtual roaming simulation and organic dose evaluation in radiation environment. SuperMC/RVIS2.3 was applied in the maintenance simulation of International Thermonuclear Experimental Reactor (ITER) poloidal field (PF) repair and target's maintenance scenario of China LEAd-based Research Reactor (CLEAR-I). The test result shows that the system makes it possible to safely perform work scenario designs and optimization, maintenance plan, emergency evaluation and operation training.

KW - Organic dose assessment

KW - Radiation protection

KW - RVIS

KW - SuperMC

KW - Virtual simulation

UR - https://www.scopus.com/pages/publications/84955095095

U2 - 10.7538/yzk.2015.49.S0.0007

DO - 10.7538/yzk.2015.49.S0.0007

M3 - 文章

AN - SCOPUS:84955095095

SN - 1000-6931

VL - 49

SP - 7

EP - 15

JO - Yuanzineng Kexue Jishu/Atomic Energy Science and Technology

JF - Yuanzineng Kexue Jishu/Atomic Energy Science and Technology

ER -

Development of virtual reality-based simulation system for nuclear and radiation safety

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Keywords

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