**Author details**

Mikhail Mikhaylovich Radkevich1 \*, Nikolay Rafailovich Vargasov1 and Boris Konstantinovich Barakhtin<sup>2</sup>

1 Peter the Great Saint Petersburg Polytechnic University, Russia

2 Saint Petersburg State Marine Technical University, Russia

\*Address all correspondence to: radmich@mail.ru

© 2019 The Author(s). Licensee IntechOpen. This chapter is distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/ by/3.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

**75**

*Characteristics of the Dissipation of Energy at Hot Plastic Deformation of Near-Alpha Titanium…*

(in Russian)

1104. (in Russian)

and Heat Treatment. St. Petersburg: Technical Publishing, St. Petersburg State Technical University; 2011. 263 p.

[10] Vargasоv NR, Barahtin BK. New approach to the assessment of the structural condition of rail steel during hot deformation. In: Materials of 4th International Scientific-Practical Conference. The Modern Mechanical Engineering. Science and Education. Peter the Great, St. Petersburg

Polytechnic University. 2014. pp. 1095-

[11] Radkevich MM. Peculiarities of structure and mechanical properties of soft mechanical and thermal processing of scientific and technical statements of St. Petersburg. Science and Education, St. Petersburg; 2008. Peter the Great, St.Petersburg Polytechnic University No. 1; 2012. p. 142 (in Russian)

[12] Titanium alloys. Metallography of titanium alloys. Moscow: Metallurgy;

1980. 464 p. (in Russian)

*DOI: http://dx.doi.org/10.5772/intechopen.88845*

[1] Kaibyshev OA. Superplasticity of Industrial Alloys. Moscow: Metallurgy;

TRANS. FR. Moscow: Metallurgy; 1982.

[3] Prasad YVRK, Sasidhara S, editors. Hot Working Guide A Compendium of Processing Maps. Bangalore: Department of Metallurgy, Indian Institute of Science; 2004. 560 p

[2] Poirier JP. High Temperature Plasticity of Metallic Bodies.

[4] Vargasov NR, Rybin VV. Optimization of temperature-rate modes of plastic deformation on the criterion of dissipation of mechanical energy. Metallography and Heat Treatment of Metals. 1999;**9**:52-56.

[5] Vargasov NR, Rybin VV.

Accumulation and dissipation of energy by hot plastic deformation of titanium alloy. Materials Science. 1999;**1**(18):63-

[6] Barakhtin BK, Nemets AM. Metals and alloys. Analysis and research. Physicoanalytical methods of study of metals and alloys. Nonmetallic Inclusions NPO "Professional", St. Petersburg; 2006. 490 p. (in Russian)

[7] Barahtin BK, Chashnikov VF. A computer program for multifractal analysis of images of structures of metals and alloys. Problems of Materials Science. 2001;**N4**(28):5-8. (in Russian)

[8] Barahtin BK, Vargasov NR. New approaches in assessing the structural and mechanical condition of the low alloy rail steel during thermal treatment. Materials Science and Engineering. 2014;**12**:8-14. (in Russian)

[9] Radkevich MM. Technology Strengthening Programme Mechanics

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**References**

*Characteristics of the Dissipation of Energy at Hot Plastic Deformation of Near-Alpha Titanium… DOI: http://dx.doi.org/10.5772/intechopen.88845*
