The Obtaining Layered Composite Materials that Contain Rare Earth Element

A. N. Burlova; Fedor Y. Isupov; Sergey Anatolyevich Kotov; Maria G. Livintsova

doi:10.4028/www.scientific.net/KEM.822.117

Paper Titles

Application of Innovational Sc-Containing Alloys in Shipbuilding
p.87

Effect of Severe Plastic Deformation on the Structure and Properties of the Aluminum Alloy System Al-Cu-Mg
p.94

Improving the Properties of Aluminum Alloy System Al-Cu-Mg, Subjected to Hardening and Severe Plastic Deformation
p.101

Joining of Titanium and its Alloys with Aluminum Alloys by Friction Stir Welding
p.109

The Obtaining Layered Composite Materials that Contain Rare Earth Element
p.117

Temperature Influence on Microstructure and Properties Evolution of Friction Stir Welded Al-Mg-Si Alloy
p.122

Comparison of Porosity Evaluation Methods Using the Example of Dissimilar Metal Joints
p.129

The Method for Determining the Friction Coefficient in Relation to the Hot Forging Processes
p.137

Improving the Quality of Parts Produced by Bending in a Die with an Elastic Element
p.144

HomeKey Engineering MaterialsKey Engineering Materials Vol. 822The Obtaining Layered Composite Materials that...

The Obtaining Layered Composite Materials that Contain Rare Earth Element

Abstract:

Materials with high content of rare-earth elements can be used for the manufacture of structural elements of containers for the transport of spent nuclear fuel. The combination of methods of powder metallurgy and methods of intensive plastic deformation allows to introduce a greater number of additives into the composition of the material than in the classical metallurgical processes. The article shows the possibility of using a combination of friction stir welding and friction stir processing in order to create a layered composite with a high content of rare-earth elements.

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Periodical:

Key Engineering Materials (Volume 822)

Pages:

117-121

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.822.117

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Online since:

September 2019

Authors:

A. N. Burlova*, Fedor Y. Isupov, Sergey Anatolyevich Kotov, Maria G. Livintsova

Keywords:

Friction Stir Processing, Friction Stir Welding, Mechanical Alloying, Powder Metallurgy, Radiation Safety, Rare Earth Elements, Transportation of Spent Nuclear Fuel

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References

[1] Yan Gor-Lessi. Nuclear power (Yadernoe electrichestvo). Rostov-on-don, Publishing house Rostizdat,, 2002, 123 p.

Google Scholar

[2] Bolshakov K.A. Chemistry and technology of rare and scattered elements (Khimiya i tekhnologiya redkikh i rasseyannykh elementov). Moscow, Higher school, 1976, 320 p.

Google Scholar

[3] Aleshin V.S., Kuznetsov N.M. Ship nuclear reactors (Sudovye yadernye reaktory). Leningrad, Shipbuilding, 1968, 492 p.

Google Scholar

[4] Malofeev S.S. Influence of intensive plastic deformation methods on the structure and properties of Al-Mg alloys (Vliyaniye metodov intensivnoy plasticheskoy deformatsii na strukturu i svoystva splavov sistemy Al-Mg). Thesis for the degree of candidate of technical sciences. Belgorod, 2016, 127 p.

DOI: 10.17223/9785946219242/356

Google Scholar

[5] Glukhov V.V., Nekrasova T.P. Economy of powder metallurgy, 2nd ed. St. Petersburg, Publishing House of Polytechnic Un-ty, 2017, 145 p.

Google Scholar

[6] Rudskoy, A.I., Naumov, A.A., Chernikov, E.V. Friction stir processing of metals is a new method of intensive plastic deformation (2014) Tsvetnye Metally, (4), pp.36-40.

Google Scholar

[7] Kolbasnikov, N.G., Mishin, V.V., Naumov, A.A., Zabrodin, A.V. Research into structure and rheological and relaxation properties of nanocrystalline beryllium at temperatures of hot rolling and research into stress relaxation kinetics in different sorts of beryllium (2014) Nanotechnologies in Russia, 9 (7-8), pp.430-440.

DOI: 10.1134/s1995078014040090

Google Scholar

[8] Golubev, I., Naumov, A., Michailov, V. Developing finite element model of the friction stir welding for temperature calculation (2014) METAL 2014 - 23rd International Conference on Metallurgy and Materials, Conference Proceedings, pp.1242-1248.

Google Scholar

[9] Kodjaspirov, G.E., Dobatkin, S.V., Rudskoi, A.I., Naumov, A.A. Production of ultrafine-grained sheet from ultralow-carbon steel by pack rolling (2007) Metal Science and Heat Treatment, 49 (11-12), pp.561-565.

DOI: 10.1007/s11041-007-0103-9

Google Scholar

[10] Mishin, V.V., Shishov, I.A., Kiselev, P.P., Matsinkevich, E.V., Rudnev, A.V., Bukin, K.V. Investigation of the possibility of improving the x-ray fluorescence spectrometer analytical characteristics due to using the superfine beryllium foils (2018) Materials Physics and Mechanics, 36 (1), pp.92-99.

Google Scholar

[11] Kolbasnikov, N.G., Mishin, V.V., Shamshurin, A.I., Zabrodin, A.V. Investigation of structure, rheological and relaxation properties, and stress relaxation kinetics in nanocrystalline beryllium at hot rolling temperatures (2014) Nanotechnologies in Russia, 9 (1-2), pp.65-72.

DOI: 10.1134/s1995078014010078

Google Scholar

[12] Mishin, V.V., Shishov, I.A. Investigation of deformation and fracture for thin beryllium foils under static loading by external pressure (2018) Materials Physics and Mechanics, 36 (1), pp.100-113.

Google Scholar

[13] Mishin, V.V., Shishov, I.A., Minchena, A. Technique of durability estimation for thin beryllium foils during their work in x-ray detectors (2018) Materials Physics and Mechanics, 38 (1), pp.40-47.

Google Scholar

[14] Mishin, V., Glukhov, P., Matveev, M., Bezobrazov, Y., Shiryaykhin,A. Microalloyed pipe line steel fracture analysis during continuous casting process (2014) METAL 2014 - 23rd International Conference on Metallurgy and Materials, Conference Proceedings, pp.192-198.

Google Scholar