Formation of Gradient Multiphase Nanostructured Surface Layers Using the Electron-Ion-Plasma Combined Method

Yurii F. Ivanov; Anton D. Teresov; Olga V. Ivanova; Victor Gromov; Evgeniy A. Budovskikh; Аnatoliy A. Klopotov

doi:10.4028/www.scientific.net/AMM.756.236

Paper Titles

Influence of Layer-by-Layer Laser Sintering Modes on the Roughness and Thickness of Sintered Layer of Copper Powder
p.214

Comparison of Activation Technologies Powder ECP-1 for the Synthesis of Products Using SLS
p.220

An Application of Spark Plasma Sintering for Compaction of Refractory Oxides and Nitrides
p.225

A Cylindrical Shell Made of Glass-Metal Composite
p.230

Formation of Gradient Multiphase Nanostructured Surface Layers Using the Electron-Ion-Plasma Combined Method
p.236

Phase Formation in the Ti-Y-O System Formed Using High-Energy Methods
p.243

Formation of Ceramic Crock Structure Made of Technogenic Raw Materials with Vanadium Component
p.250

Development of Composition and Research of Rheological Properties of Thermoplastic Slips on the Basis of Aluminium Nitride
p.257

Hardening of Metallurgical Machinery Components by Facing with Heatproof, Hard Steels and Low Temperature Pre-Heating
p.263

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 756Formation of Gradient Multiphase Nanostructured...

Formation of Gradient Multiphase Nanostructured Surface Layers Using the Electron-Ion-Plasma Combined Method

Abstract:

The data of the study of the elemental and phase composition, the condition of the defect substructure, mechanical and tribological characteristics of titanium alloy VT6 subjected to electroexplosive carburization with a sample of titanium diboride powder and the subsequent treatment by high-intensity pulsed electron beam is presented. It has been established that the main mechanisms responsible for an increase in the mechanical and tribological properties of the material are solid, dispersion, and grain boundary.

You might also be interested in these eBooks

Mechanical Engineering, Automation and Control Systems

View Preview

Info:

Periodical:

Applied Mechanics and Materials (Volume 756)

Pages:

236-242

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.756.236

Citation:

Cite this paper

Online since:

April 2015

Authors:

Yurii F. Ivanov*, Anton D. Teresov, Olga V. Ivanova, Victor Gromov, Evgeniy A. Budovskikh, Аnatoliy A. Klopotov

Keywords:

Dispersion-Hardened Coatings, Electrical Explosion, Plasma, Submicrostructure, Titanium Alloy, Titanium Diboride

Export:

RIS, BibTeX

Price:

Permissions:

Request Permissions

* - Corresponding Author

References

[1] R.A. Andrievskiy, I.I. Spivak, The strength of refractory compounds and materials on its basis. Handbook. Chelyabinsk: Metallurgy, 1989, 368 p.

Google Scholar

[2] I.G. Sizov, N.N. Smirnyagina, A.P. Semenov, Peculiarities of electron-beam steel boriding, Metal science and thermal treatment of metals. 12 (1999) 8– 11.

Google Scholar

[3] High-energy processes of materials processing / O.A. Solonenko, A.P. Alkhimov, V.V. Marusin, etc. Novosibirsk: Science. Siberian Publishing House of RAS, 2000, 452 p.

Google Scholar

[4] Yu.N. Tyurin, M.L. Zhadkevich, Plasma hardening technologies. Kiev: Naukova Dumka, 2008, 216 p.

Google Scholar

[5] V.A. Gribkov, F.I. Grigoriev, B.A. Kalin, V.L. Yakushin, Advanced radiation-beam technologies of metal processing. Moscow: Krugliy god, 2001, 528 p.

Google Scholar

[6] A. Ya. Bagautdinov, E.A. Budovskikh, Yu.F. Ivanov, V.E. Gromov, Physical basis of electroexplosive alloying of metals and alloys, Novokuznetsk: Publishing house of SibGIU. 2007, 301 p.

Google Scholar

[7] S.V. Karpiy, M.M. Morozov, Yu.F. Ivanov, V. E Gromov, Structure, phase composition, and properties of titanium after electroexplosive alloying and electron-beam treatment. Novokuznetsk: Publishing house of NPK, 2010, 173 p.

DOI: 10.15407/ufm.11.03.273

Google Scholar

[8] N.N. Koval, Yu.F. Ivanov, Surface nanostructuring of metal and ceramic materials under pulsed electron-beam treatment, Russian Physics Journal. 5 (2008) 60-70.

Google Scholar

[9] V Rotshtein, Yu. Ivanov, A. Markov, Surface treatment of materials with low-energy, high-current electron beams. Chapter 6 in the Book Materials surface processing by directed energy techniques,. Ed. by Y. Pauleau. Paris: Elsevier. 2006. pp.205-240.

DOI: 10.1016/b978-008044496-3/50007-1

Google Scholar