Paper Titles

Research of the Possibility of Obtaining a Foam System of Aluminum - Carbon Nanotubes Using a High-Temperature Foam Agent
p.239

Effect of High Energy Ball Milling Washing Process on Properties of Nd₂Fe₁₄B Particles Obtained by Reduction-Diffusion
p.244

The Technology of Producing Layered Composite Materials on the Basis of Hypoeutectic Silumin AK9ch and Sintered Iron Powder AHC100.29
p.252

Consolidation Behavior of the Cu-Al₂O₃ Nanocomposite Powder
p.258

General Method of Research of Electrophysical Properties of Nanostructured Composites
p.264

Obtaining a Hard Alloy Powder from a Worn-Out Tools with a Subsequent Use for Pressing Rods
p.270

Comparison of Supermacroporous Polyester Matrices Fabricated by Thermally Induced Phase Separation and 3D Printing Techniques
p.277

The Research and Development of the Technology for Pressure Treatment of the Thermally Expanded Graphite Powders
p.284

Correlation of Nonuniformities of the Seebeck Coefficient’s Distribution and the Strain-Stress State in Extruded Thermoelectric Material
p.291

HomeKey Engineering MaterialsKey Engineering Materials Vol. 822General Method of Research of Electrophysical...

General Method of Research of Electrophysical Properties of Nanostructured Composites

Article Preview

Abstract:

The paper presents an information model and a general methodology for studying the electrophysical properties of materials and products from nanostructured composites. The information model of the original methodology for the standard process of experimental measurement and study of the electrophysical properties of composites comprehensively takes into account the characteristics associated with their industrial production (quality assurance systems, safety, certification, etc.) in order to develop experimental measurement methods and new standards, including standards of enterprises, methodological guidelines, work programs for the development of high-tech production advanced materials and products.

You might also be interested in these eBooks

New Materials and Technologies in Mechanical Engineering

Info:

Periodical:

Key Engineering Materials (Volume 822)

Pages:

264-269

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.822.264

Citation:

Cite this paper

Online since:

September 2019

Authors:

Gennady Konstantinovich Baryshev*, Aleksandr Vasilievich Berestov, Anton Nikolaevich Tokarev, Anastasia Kondrateva, Polina Olegovna Chernykh

Keywords:

Electrophysical Properties, Nanostructured Composites

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

© 2019 Trans Tech Publications Ltd. All Rights Reserved

Share:

Citation:

* - Corresponding Author

[1] National Security Strategy of the Russian Federation until 2020, approved by Decree of the President of the Russian Federation on May 12, 2009 №537.

[2] Bobkova T. I., Farmakovskii B. V., Bogdanov S. P. Creation of composite nanostructured surface-reinforced powder materials based on Ti/WC and Ti/TiCN used for coatings with enhanced hardness //Inorganic Materials: Applied Research. – 2016. – V. 7. – №. 6. – pp.855-862.

DOI: 10.1134/s2075113316060034

[3] V. M. Baranov, A. M. Karasevich, G. A. Sarychev, Testing and quality control of materials and structures: textbook for universities, High School, Moscow, (2004).

[4] Surin V.I., Evstyukhin N.A., Electrophysical methods of non-destructive testing and research of reactor materials, MEPhI, Moscow, (2008).

[5] A.V. Putilov, A.K. Shikov, V.I. Pantsyrny, A.E. Vorobyova, V.A. Drobyshev, Creation of superstrong nanostructured microcompositional electrotechnical Cu – Nb wires by plastic deformation, Non-ferrous metals. 3 (2008) 77-83.

[6] A.I. Voronin, G.K. Baryshev, Y.V. Bozhko, A.A. Usenko, V.Y. Zueva, K.I. Litvinova, I.V. Petrova, M.A. Seredina, V.V. Hovailo. Features of sintering processes of Heusler alloys Ni (M) Sn (M = Ti, Zr, Hf), Brief Communications on Physics of the Physics Institute. PN Lebedev Russian Academy of Sciences., Publisher: Physical Institute. PN Lebedeva RAS (Moscow), 2015, V. 42, No. 7, pp.47-53.

DOI: 10.3103/s1068335615070064

[7] RMG 29-99. State system for ensuring uniformity of measurements. Metrology. Basic terms and definitions.

[8] IAEA safety standards series (2007).

[9] Andronov A. et al. Characterization of thin carbon films capable of low-field electron emission //Journal of Vacuum Science & Technology B, Nanotechnology and Microelectronics: Materials, Processing, Measurement, and Phenomena. – 2018. – V. 36. – №. 2. – С. 02C108.

DOI: 10.1116/1.5009906

[10] Kazakov A. et al. Quantitative Characterization of Hypoeutectic Aluminum–Silicon–Copper As-Cast Alloy Microstructures //Materials Performance and Characterization. – 2016. – V. 5. – №. 5. – pp.497-509.

DOI: 10.1520/mpc20160025

[11] Karkhin V. A., Khomich P. N., Rayamaki P. Analysis of chemical macroheterogeneity in the vicinity of the fusion boundary in fusion welding //Welding International. – 2010. – V. 24. – №. 2. – pp.125-130.

DOI: 10.1080/09507110903292114

[12] Skotnikova M. A. et al. Structural and phase transformation in material of blades of steam turbines from titanium alloy after technological treatment //Advances in Mechanical Engineering. – Springer, Cham, 2015. – pp.93-101.

DOI: 10.1007/978-3-319-15684-2_12

[13] Kondrat'ev S. Y., Shvetsov O. V. Effect of high-temperature heating on the structure and properties of aluminum alloys in the production of drill pipes //Metal Science and Heat Treatment. – 2013. – V. 55. – №. 3-4. – pp.191-196.

DOI: 10.1007/s11041-013-9604-x

[14] Kondrat'ev S. Y., Yaroslavskii G. Y., Chaikovskii B. S. Classification of high-damping metallic materials //Strength of Materials. – 1986. – V. 18. – №. 10. – pp.1325-1329.

DOI: 10.1007/bf01523261

[15] Imayev V. et al. Extraordinary superplastic properties of hot worked Ti–45Al–8Nb–0.2 C alloy //Journal of Alloys and Compounds. – 2016. – V. 663. – pp.217-224.

DOI: 10.1016/j.jallcom.2015.11.228

[16] Tsemenko V. N. et al. Fabrication, Structure and Properties of a Composite from Aluminum Matrix Reinforced with Carbon Nanofibers //Metal Science and Heat Treatment. – 2018. – pp.1-8.

DOI: 10.1007/s11041-018-0235-0

[17] Mechanical behavior of structural materials. Translated from German. Textbook / I. Resler, H. Harders, M. Becker - Dolgoprudny Publishing House Intellect,, 2011. - 504 p.

[18] McClintock, F., Argon, A. Deformation and destruction of materials M.: Mir, 1970. - 443 p.

[19] J.V. Foltz: Metal-matrix composites. In J.R. Davis (editor): Nonferrous Alloys and Special Purpose Materials, volume 2 of ASM Handbook: Properties and Selection. ASM International, (1990).

DOI: 10.31399/asm.hb.v02.9781627081627

[20] B.W. Rosen: Analysis of material properties. In T.J. Reinhart (editor): Composites, volume 1 of Engineering Materials Handbook, pages 185-205. ASM International, (1987).

[21] Baryshev G.K., Tutnov I.A., Biryukov A.P., Perspectives and principles of formulation of legal basis of diagnostic quality measurement and control of materials and products of nanostructure composites, MATEC Web of Conferences. – 2017. – Vol. 129. International Conference on Modern Trends in Manufacturing Technologies and Equipment 2017 (ICMTME 2017). – 02036.

DOI: 10.1051/matecconf/201712902036

[22] Baryshev G.K., Kondratyeva A.S., Berestov A.V., Development of methodical instruments of obtaining, research and control of electrophysical service properties of nanostructure composites // MATEC Web of Conferences. – 2017. – Vol. 129. International Conference on Modern Trends in Manufacturing Technologies and Equipment 2017 (ICMTME 2017). – 02037.

DOI: 10.1051/matecconf/201712902037

[23] Patent for invention RU 2650731 «Method for studying the anisotropy of operational and technological properties of objects», G01N 27/02, (2018).