Issue 24

Andrey E. Buzyurkin et alii, Frattura ed Integrità Strutturale, 24 (2013) 102-111; DOI: 10.3221/IGF-ESIS.24.11 111 Ux, cm/msec T, K 0.2 0.8 0.6 0.4 0.2 0.8 0.6 0.4 300 100 200 -0.25 0.25 0 0.5 Y, cm Y, cm Figure 18 : Distributions of the longitudinal velocity x u (a) and temperature T (b) across the compacted region of the sample for the detonation velocity = 3 D km/s. C ONCLUSIONS oint theoretical and experimental studies have allowed to implement an approach that uses mathematical and physical simulation of shock-wave loading of powdered materials. A numerical simulation of shock wave propagation and deformation of the experimental assembly has been performed. The temperature distributions over the sample thickness in the compacted zone for several values of detonation velocity show that at higher speeds there is considerable heterogeneity in the temperature distribution over the sample thickness. Near the axis of the sample the temperature has a higher value than in distance from it. An increase in the pressure decay time due to increasing either the explosive thickness or the external loading intensity causes no shrinkage of the destruction zone at a fixed propagation velocity of the detonation wave. Compaction of powders with low detonation velocities results in a considerable shrinkage of destruction zones in finish samples and in a uniform distribution of material parameters in the compacted region. R EFERENCES [1] V.F. Nesterenko, High-rate deformation of heterogeneous materials, Nauka, Novosibirsk (1992) (in Russian). [2] R. Prümmer, Powder compaction. Explosive welding, forming and compaction, London; New York: Appl. Sci. Publ., (1983). [3] S.P. Kiselev, V.M. Fomin, J. of Applied Mechanics and Technical Physics. 34(6) (1993) 861. [4] V.V. Pai, G.E. Kuz'min, I.V. Yakovlev, Combustion, Explosion, and Shock Waves, 31(3) (1995) 124. [5] A.I. Gulidov, I.I. Shabalin, Numerical Realization of the Boundary Conditions in Dynamic Contact Problems, Preprint ITAM SB RAS, Novosibirsk (1987) (in Russian). [6] M. L. Wilkins, Computer simulation of dynamic phenomena, Springer, Berlin, Heidelberg (1999). [7] E. I. Kraus, Vestnik NGU. Fizika, 2(2) (2007) 65 (in Russian). [8] C. Slater, Introduction in the chemical physics.– New-York-London: McGraw Book company, Inc., (1935) 239. [9] L. D. Landau, K.P. Stanyukovich, Dokl. Akad. Nauk SSSR, 46 (1945) 399 (in Russian). [10] J. S. Dugdale, D. McDonald, Phys. Rev., 89 (1953) 832. [11] V.Ya. Vaschenko, V.N. Zubarev, Sov. Phys. Solid State, 5 (1963) 653. [12] R. G. McQueen, S. P. Marsh, J. W. Taylor, J. N. Fritz, High-Velocity Impact Phenomena, ed. by R. Kinslow, New York: Academic Press (1970) 293. J