The development and application of the digital twins of nuclear propulsion plants (TNPP) and nuclear power plants (NPP) in order to increase operational safety and economic efficiency are considered. The TERMIT technology for automating the simulation process for developing complex computational models of different classes and purpose for full-scale simulation of dynamic processes occurring in nuclear facilities is presented. The directions and results of the application of this technology are presented.
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References
GOST R 57700.21-2020, Computer Modeling in the Development, Production, and Operation of Manufactured Products. Terms and Definitions, Standartinform, Moscow (2020).
D. V. Lyalyuev, “Efficient computational algorithms for automating the simulation of non-stationary processes in thermohydraulic networks of TNPP in real time,” Tekhnol. Obesp. Zhizn. Tsik. Yad. Energ. Ustan., No. 1(1), 38–51 (2015).
D. V. Lyalyuev and A. A. Shaleninov, “Automation system for the development and maintenance of functional and special software for simulators and analyzers of TNPP – TERMIT-D,” Vopr. At. Nauki Tekhn. Ser. Fiz. Yad. Reakt., No. 2, 130–146 (1999).
D. V. Lyalyuev, V. A. Vasilenko, and A. A. Shaleninov, “TERMIT CAD tools for development and maintenance of software for NPP simulators and analyzers,” in: Proc. Ann. Meeting of Nuclear Technology’2000, Germany (2000), pp. 427–430.
R. D. Filin, Yu. A. Migrov, and V. G. Korotaev, “KORSAR/BR software package for calculations to substantiate the safety of block and integrated reactors and VVER-type reactors,” Tekhnol. Obesp. Zhizn. Tsik. Yad. Energ. Ustan., No. 2(2), 6–15 (2015).
I. A. Byrkov, A. V. Ipatov, and D. V. Lyalyuev, “Full-scale and functional simulators for the training of operational personnel of the universal nuclear icebreaker of the next-generation project 22220,” Tekhnol. Obesp. Zhizn. Tsik. Yad. Energ. Ustan., No. 4 (18), 26–34 (2019).
V. A. Vasilenko, E. I. Derbukov, and V. N. Zimakov, “End-to-end integrated technology for creating control systems for nuclear power plants,” in: Systems of Management and Information Processing: Scientific and Technical Collection of NPO Aurora, St. Petersburg (2001), Iss. 3, pp. 7–13.
V. N. Zimakov, “On the experience of developing and using a new technology for debugging control systems,” Avtomatiz. Prom., No. 7, 78–83 (2008).
S. V. Batrakov, E. I. Derbukov, and V. A. Efimov, “Technology for designing and debugging the software for the control system of a test-stand TNPP using tool-software modeling complexes,” Tekhnol. Obesp. Zhizn. Tsik. Yad. Energ. Ustan., No. 2(8), 26–39 (2017).
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Translated from Atomnaya Énergiya, Vol. 132, No. 2, pp. 93–99, February, 2022.
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Lyalyuev, D.V. TERMIT – Technology of Automated Simulation – an Instrumental Graphic Environment for Developing Digital Twins, Training Simulators, and Simulating Complexes of Nuclear Propulsion Reactor Plants and Nuclear Power Plant Units. At Energy 132, 96–101 (2022). https://doi.org/10.1007/s10512-023-00910-x
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DOI: https://doi.org/10.1007/s10512-023-00910-x