For Libraries For Publication Open Access Downloads About Us Contact Us
Paper Titles
Evaluation of the Influence of the Conditions of Catalytic Continuous Steam Explosive Activation of Wood on the Physical and Operational Properties of Wooded Composite Materials Based on Activated Fibers
p.129
Nanomodified Epoxy Materials with Improved Operating Characteristics
p.138
Physicochemical WPC Modification Techniques
p.144
Testing of Carbon Nanotubes and their Influence on the Physical and Mechanical Characteristics of Polyester Resin
p.151
Fundamentally New Composite Materials of Fast Reactors Made on the Basis of Nanotechnology
p.159
Redox Behavior of Chelate Complexes Based on 8-Oxyquinoline Promising in OLED Display Technology
p.165
Purification of Zinc Oxide from Chlorides Using Microwave Radiation
p.172
Direct Synthesis of Titanium Nanoparticles by Induction Flow Levitation Technique
p.178
Polychelates Based on Magnesium, Aluminum, Iron, Zirconium, and Vanadyl Acetylacetonates - Synthesis, Structure and Properties
p.184

Fundamentally New Composite Materials of Fast Reactors Made on the Basis of Nanotechnology

Article Preview

Abstract:

The main goal of the work is to identify the advantages of fast reactors when using nanotechnology in the manufacture of core materials. The research methods are based on the adaptation of known technologies (including powder metallurgy) to the design of fast reactors and on the numerical simulation of physical processes carried out using computer programs for the analysis of emergency conditions of fast reactors (including anticipated transient without scram - ATWS). The results of the research show that the use of structural materials based on steels hardened by nanooxides in combination with fundamentally new types of fuel based on composite materials can significantly improve the safety of nuclear technics. Sintered mixtures of ceramic microgranules (oxide, nitride) and nanoadditives of metallic beryllium or uranium are considered as nuclear fuel. Such composite nuclear fuel improves reactor safety and power. The following types of composite fuel were analyzed: mixed oxide with additives of a beryllium or uranium nanopowder, mixed mononitride with additives of a beryllium or uranium nanopowder. Most preferably, a ceramic-metal pellet fuel based on mononitride microgranules and uranium metal nanopowder. The use of such fuel (with a volume fraction of metallic uranium up to 20%) significantly increases the safety of the reactor, combining the advantages of metal and ceramics and completely neutralizing their disadvantages. The proposed materials are of practical importance in the development of new concepts of nuclear technics, in the transition to large-scale nuclear power and high-power reactors. The use of a new cermet-based composite fuel increases the power of the reactor and significantly increases the safety of the reactor.

You might also be interested in these eBooks
FarEastCon - Materials and Construction III View Preview

Info:

Periodical:

Key Engineering Materials (Volume 887)

Pages:

159-164

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.887.159

Citation:

Cite this paper

Online since:

May 2021

Authors:

V.S. Okunev*

Keywords:

Ceramic Fuel, Coatings, Composite Fuel, Emergency Conditions, Liquid Metal Fast Reactors, Nanotechnology, Safety

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

© 2021 Trans Tech Publications Ltd. All Rights Reserved

Share:

Citation:

* - Corresponding Author

References

[1] M.A. Orlov, V.V. Orlov, E.A. Orlova, Harmonization of the Nitride Fuel Element Properties by Means of a Corrosion-Resistant Heat-Conducting Pb-Mg-Zr Sublayer, in: Innovative Design and Technologies of Nuclear Power, Russia, Moscow, JSC NIKIET, 2018, 473-482.

Google Scholar

[2] D.P. Shornikov, M.A. Burlakova, B.A. Tarasov, Obtaining and compaction by methods of plasma-spark and electric pulse sintering of nanopowders of uranium nitride, Vector of science TSU. 3 (2013) 95-98.

Google Scholar

[3] M. Tokita, Development of Advanced Spark Plasma Sinyering (SPS) Systems and its Applications, Ceramic Transaction. 194 (2006) 51-60.

Google Scholar

[4] V.N. Polovinkin, Nanotechnology in the energy sector, Agency PRoATOM, 11 Jan., 2010. (Information on http://www.proatom.ru/modules.php?name=News&file=article&sid=2118).

Google Scholar

[5] N.A. Azarenkov, V.N. Voevodin, V.G. Kirichenko, G.P. Kovtun, Nanostructured materials in nuclear energy, Bulletin of Kharkiv University, Series physical: Nuclei, particles, fields,. 887-1 (2010) 4-24.

Google Scholar

[6] V.V. Saragadze, V.A. Shabashov, A.V. Litvinov, Reinforced steel steels reinforced by nano oxides, in: 6th Int. Seminar Radiation Physics of Metals and Alloys,, Snezhinsk, 2005, p.78.

Google Scholar

[7] V.S. Okunev, Substantiation of the Feasibility of Using Fuel Rods with Tungsten Spraying in Power Fast Reactors of New Generation, Thermal Engineering. 58/14 (2011) 1167-1171.

DOI: 10.1134/s0040601511140060

Google Scholar

[8] V.S. Okunev, Nanotechnology in nuclear power engineering: pellet cermet MOX-U and MN-U-fuel for fast reactors, in: Innovate Design and Technologies of Nuclear Power, Russia, Moscow, JSC NIKIET, Publ. 2016, vol. 1, pp.195-206.

Google Scholar

[9] O.J. Wick (editor), Plutonium Handbook, New-York-London-Paris: Gordon and Breach, Science Publishers. vol. 2. (1967).

Google Scholar

[10] A.A. Maershin, V.A. Tsykanov, V.N. Golovanov, et al., Development and testing of fuel rods of fast reactors with vibro-compacted oxide fuel, Atomic energy. 91/5 (2001) 378-385.

Google Scholar

[11] O.V. Skiba, A.A. Maershin, P.T. Porodnov, A.V. Bychkov, The fuel cycle of nuclear reactors based on dry" methods of fuel processing, vibration compaction technology and automated fuel rod manufacturing processes, in: Closed fuel cycle: pyroelectrochemistry, technology of vibration compaction, fuel elements, Dimitrovgrad, "NIIAR,, 1994, Issue. 1, pp.3-13.

DOI: 10.1016/b978-0-323-99308-1.00025-8

Google Scholar

[12] Yu.S. Fedorov, B.E. Burakov, V.M. Garbuzov, Russian Patent, 2459289 (2011).

Google Scholar

[13] V.S. Okunev, Accident Tolerant Materials for LMFR, IntechOpen, Open access peer-reviewed chapter – ONLINE FIRST.

Google Scholar

[14] A.M. Kuzmin, V.S. Okunev, Using variational methods to solve the problems of ensuring and substantiating the natural safety of fast neutron reactors, Russia, Moscow, MEPhI,(1999).

Google Scholar

[15] V.S. Okunev, Designing of New Generation of the Nuclear Reactors. AIP Conference Proceedings 2195, 020012 (2019), https://doi.org/10.1063/1.5140112.

Google Scholar

[16] IAEA-TECDOC-1139: Transient and accident analysis of a BN-800 type LMFR with near zero void effect. IAEA, Vienna, Austria (2000).

Google Scholar

[17] E.O. Adamov, V.V. Orlov (editors), BREST-OD-300, Russia, Мoscow, NIKIET, (2001).

Google Scholar

[18] H. Khammel, D. Okrent, Reactivity Coefficients in Large Fast Power Reactors, Argonne National Laboratory, American Nuclear Society Publ., (1970).

Google Scholar

[19] V.S. Okunev, The basis of applied nuclear physics and introduction into physics of nuclear reactors, Series Physics in Technical University,, Russia, Moscow: Bauman Moscow State Technical University, (2015).

DOI: 10.18698/2309-7604-2015-1-165-170

Google Scholar

[20] G.J. Van Tuyle, P.G. Kroeger, G.C. Slovik, et.al., Examing the Inherent Safety of PRISM, SAFR, and the MHTGR, Nuclear Technology. 91 (1990) 185-202.

DOI: 10.13182/nt90-a34427

Google Scholar

© 2025 Trans Tech Publications Ltd. All rights are reserved, including those for text and data mining, AI training, and similar technologies. For open access content, terms of the Creative Commons licensing CC-BY are applied.
Scientific.Net is a registered trademark of Trans Tech Publications Ltd.