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Simulation of the Action of a Shock Wave on Titanium Alloy

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Journal of Engineering Physics and Thermophysics Aims and scope

The laws and mechanism of fracture of coarse-grain and ultrafine-grain titanium under shock-wave loading has been investigated. For the shock wave generator a "SINUS-7" accelerator emitting a nanosecond relativistic highcurrent electron beam was used. To test the high-velocity impact at velocities of the order of 2500 m/s, a ballistic installation of caliber 23 mm was used. The mathematical simulation of the high-velocity interaction was carried out with account for the fracture, the phase transitions, and the dependence of the strength characteristics of materials on the internal energy within the framework of continuum mechanics. For both granular structures the general laws and features of the fracture have been established.

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References

  1. E. F. Dudarev, A. N. Tabachenko , G. P. Bakach, G. P. Pochivalova, A. B. Skosyrskii, M. F. Zhorovkov, A. B. Markov, M. D. Kitsanov, E. V. Yakovlev, A. E. Maier, O. A. Kashin, S. A. Afanas′eva, N. N. Belov, M. V. Khabibullin, and N. T. Yugov, Laws and mechanisms of split-off tracture of ultramicrogranular fcc of metals and alloys exposed to a nanosecond relativistic electron beam, Izv. Vyssh. Ucheb. Zaved., Fizika, 56, No. 7/3, 44–46 (2013).

  2. S. A. Afanas′eva, N. N. Belov, Yu. A. Biryukov, V. V. Burkin, V. M. Zakharov, A. N. Ishchenko, A. B. Skosyrskii, A. N. Tabachenko, I. E. Khorev, and N. T. Yugov, Investigation of shock-wave phenomena in composite materials, J. Eng. Phys. Thermophys., 84, No. 1, 49–58 (2011).

  3. V. A. Burakov, V. V. Burkin, A. N. Ishchenko, L. V. Korol′kov, E. Yu. Stepanov, A. V. Chupashev, S. V. Agafonov, and K. S. Rogaev, Experimental Ballistic Complex, Patent application, Reg. No. 2015113676 of 13.04.2015, Federal Service for Intellectual Property, Patents, and Trademarks (Rospatent).

  4. M. V. Khabibullin and S. A. Afanas′eva, Calculation of the Phenomena Occurring in Condensed Media Exposed to Intense Pulses (in Axisymmetric Formulation), Federal Service for Intellectual Property, Patents, and Trademarks (Rospatent), Certificate of state registration of a computer program of 14.08.2012 No. 2012617301, Moscow.

  5. A. I. Potekaev, A. N. Tabachenko, V. M. Savostikov, E. F. Dudarev, G. P. Bakach, and A. B. Skosyrskii, High-strength submicrocrystalline (α + β)-titanium alloys with a nanocomposition antifriction wear-resistant coating, Izv. Vyssh. Ucheb. Zaved., Fiz., 57, No. 2, 77–84 (2014).

  6. N. N. Belov, V. N. Demidov, L. V. Efremova, A. V. Zhukov, A. P. Nikolaev, V. G. Simonenko, V. G. Trushkov, M. V. Khabibullin, I. E. Shipovskii, and V. B. Shutalev, Computer simulation of the dynamics of a high-velocity impact and the accompanying physical phenomena, Izv. Vyssh. Ucheb. Zaved., Fiz., No. 8, 5–48 (1992).

  7. E. F. Dudarev, S. A. Afanas′eva, G. P. Bakach, N. N. Belov, A. B. Markov, A. N. Tabachenko, M. V. Khabibullin, N. T. Yugov, and T. Yu. Maletkina, Fracture of coarse-grained and ultramicrogranular titanium under quasi-static and impact loading, Izv. Vyssh. Ucheb. Zaved., Fiz., 57, No. 11, 12–17 (2014).

  8. N. Fomin, E. Lavinskaya, and D. Vitkin, Speckle tomography of turbulent flows with density fluctuations, Exp. Fluids, 33, 160−169 (2002).

    Article  Google Scholar 

  9. N. Fomin, W. Merzkirch, D. Vitkin, and H. Wintrich, Visualization of turbulence anisotropy by single exposure speckle photography, Exp. Fluids, 20, 476−479 (1996).

    Article  Google Scholar 

  10. D. Vitkin, W. Merzkirch, and N. Fomin, Quantitative visualization of the change of turbulence structure caused by a normal shock wave. J. Visualization, 1, No. 1, 29−35 (1998).

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Authors and Affiliations

  1. National Research Tomsk State University, 36 Lenin Ave., Tomsk, 634050, Russia

    S. A. Afanas’eva, N. N. Belov, V. V. Burkin, E. F. Dudarev, A. N. Ishchenko, K. S. Rogaev, E. F. Dudarev, A. N. Ishchenko & K. S. Rogaev

Authors
  1. S. A. Afanas’eva
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  2. N. N. Belov
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  3. V. V. Burkin
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  4. E. F. Dudarev
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  5. A. N. Ishchenko
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  6. K. S. Rogaev
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  7. E. F. Dudarev
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  8. A. N. Ishchenko
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  9. K. S. Rogaev
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Corresponding author

Correspondence to S. A. Afanas’eva.

Additional information

Translated from Inzhenerno-Fizicheskii Zhurnal, Vol. 90, No. 1, pp. 29–39, January–February, 2017.

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Afanas’eva, S.A., Belov, N.N., Burkin, V.V. et al. Simulation of the Action of a Shock Wave on Titanium Alloy. J Eng Phys Thermophy 90, 24–34 (2017). https://doi.org/10.1007/s10891-017-1535-8

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  • DOI: https://doi.org/10.1007/s10891-017-1535-8

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