Methods of Uranium Hexafluoride Purification

Aleksey A. Orlov; Roman Malyugin

doi:10.4028/www.scientific.net/AMR.1084.46

Paper Titles

Influence of Carbon Pulse Ion Beam on Titanium Alloy
p.30

Investigation of Multilayered Film Structure Properties for Creation of Hydrogen Selective Membrane
p.34

Investigation of ZrO₂ and TiO₂ Coatings Influence on Hydrogen Sorption Behavior by Zirconium Alloy Zr1%Nb at Saturation from Gas Atmosphere
p.38

Laws of Radiation Grafting of Styrene to PVDF Films and Characterization of the Grafted Polymer
p.42

Methods of Uranium Hexafluoride Purification
p.46

Obtaining Hydrogen and Carbon Materials from Hydrocarbonic Gas in Microwave Plasma Discharge at Amospheric Pressure
p.50

Study on the Spatial Structure of Ultrafine-Grained Light Alloys by Microtomography
p.54

Technology of Synthesis of Opal Matrix Metamaterials
p.58

Temperature Effect on the Rate of Hydrogen Desorption by Carbon Materials
p.61

HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 1084Methods of Uranium Hexafluoride Purification

Methods of Uranium Hexafluoride Purification

Abstract:

The article contains an analytical overview of techniques used for UF₆ purification. Structures of respective devices have been considered. Their advantages and drawbacks have been outlined. It has been shown that heat discharge desublimators and multi-chamber devices with two heated walls are the most efficient in UF₆ purification.

You might also be interested in these eBooks

Radiation and Nuclear Techniques in Material Science

View Preview

Info:

Periodical:

Advanced Materials Research (Volume 1084)

Pages:

46-49

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.1084.46

Citation:

Cite this paper

Online since:

January 2015

Authors:

Aleksey A. Orlov*, Roman Malyugin

Keywords:

Desublimation, Gas Centrifuge, Gas-Vapor Mixture, Uranium Hexafluoride

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] Yu. Tymanov, Plasma and high-receipt and processing of materials in the nuclear fuel cycle: present and future, Fizmatlit, Moscow, 2003 (in Russian).

Google Scholar

[2] G. Andreev, A. Djachenko, Fluoride technology in the production of nuclear fuel, TPU Publishing, Tomsk, 2013 (in Russian).

Google Scholar

[3] G. Andreev, A. Djachenko, Introduction to Chemical technology nuclear fuel, TPU Publishing, Tomsk, 2008 (in Russian).

Google Scholar

[4] B. Belozerov, I. Rusakov, G. Andreev, A. Zhiganov, Yu. Kobzar, Analysis of the process and apparatus for sublimation of uranium hexafluoride and other volatile fluorides, Non-ferrous metals. 1 (2012) 58-61.

Google Scholar

[5] S. Gubanov, A. Krainov, Mathematical model and numerical results of the collecting cooling capacities under desublimation flow UF6 and light impurities, Tomsk state university journal. 20 (2012) 56-65.

Google Scholar

[6] S. Gubanov, A. Krainov, Numerical simulation of cooling tanks desublimation vapor, Computer studies and simulations. 3 (2011) 383-388.

DOI: 10.20537/2076-7633-2011-3-4-383-388

Google Scholar

[7] A. Orlov, S. Koshelev, V. Vandushev, L. Chernov, G. Shopen, I. Ilin, V. Gordienko, Mathematical modeling of desublimation UF6, Bulletin of Tomsk Polytechnic University. 309 (2009) 89-92.

Google Scholar

[8] V. Ainshtain, M. Zaharov, G. Nosov, The general course of processes and devices of chemical technology, Himija, Moscow, 2002 (in Russian).

Google Scholar

[9] A. Maslov, G. Kaliackaya, G. Amelina, A. Vodiankin, N. Egorov, Technology of uranium, TPU Publishing, Tomsk, 2007 (in Russian).

Google Scholar

[10] B. Belozerov, A. Volodin, A. Gushchin, V. Korotkevich, V Korobcev, V. Lazarchuk, E. Marinenko, E. Maluy, A. Rudhikov, V. Hohlov, RF Patent 2143940 (2000).

Google Scholar

[11] V. Tkachev, O. Grechishkin, A. Danilov, M. Vaskov, A. Starugin, A. Polievec, A. Sheldiaev, RF Patent 2508149 (2014).

Google Scholar

[12] I. Rusakov, Yu. Makasaev, RF Patent 2487742 (2013).

Google Scholar

[13] I. Rusakov, A. Volodin, V. Kazimirov, E. Eremin, Yu. Makasaev, V. Stolbov, M. Chepezybov, A. Blohin, A. Majorov, V. Dmitrienko, RF Patent 2462287 (2012).

Google Scholar

[14] I. Rusakov, A. Volodin, V. Kazimirov, E. Eremin, Yu. Makasaev, V. Stolbov, M. Chepezybov, A. Blohin, A. Majorov, V. Dmitrienko, RF Patent 2467780 (2012).

Google Scholar