Profiled Detonation Waves in the Technologies of Explosion Treatment of Metals

V. V. Sobolev$^{1}$, O. V. Skobenko$^{1}$, М. M. Kononenko$^{1}$, V. V. Kulivar$^{1}$, А. V. Kurlyak$^{2}$

$^{1}$Национальный технический университет «Днепровская политехника», просп. Дмитрия Яворницкого, 19, 49005 Днепр, Украина
$^{2}$State Enterprise “Scientific and Production Association ‘Pavlohrad Chemical Plant’”, 44 Zavodska Str., UA-51402 Pavlohrad, Ukraine

Получена: 08.06.2023; окончательный вариант - 15.07.2023. Скачать: PDF

A short review is represented concerning physicotechnical features of current technologies, plane-wave, converging cylindrical and spherical detonation waves used in physics and chemistry of high energy densities, physics of metals, materials science, machine building, and mining and metallurgical industry. The main drawbacks of existing technologies are shown, and attention is focused on the technical nature of the reasons limiting their application. Attention is paid to solving the problem of simultaneous initiation of detonation of the entire surface layer of a light-sensitive explosive, regardless of the shape of the surface. A physical and mathematical methodology for estimating shock-wave parameters of an explosive during initiation of detonation in it by explosion of the initiation layer of the charge of a light-sensitive explosive composite is proposed. Prospects of practical application of detonation (shock) waves of the specified profile formed by laser ignition of the surface of a light-sensitive explosive composite are discussed. Physicochemical potential of the system of laser initiation of detonation makes it possible to form any wave profiles and get pulses of the intensity from 0.1 to 1.0 kPa$\cdot$s on the surfaces being more than 1 m$^{2}$. Precision and safe system of laser initiation can be used during any types of blasting operations including the ones that cannot be implemented principally, while applying standard systems for initiating explosives and means of explosion.

Ключевые слова: light-sensitive explosion composite, laser, radiation, chemical reactions, detonation, wave fronts, shockwaves, super-short pulse.

URL: https://mfint.imp.kiev.ua/ru/abstract/v45/i11/1349.html

PACS: 42.60.Jf, 47.40.Rs, 62.50.Ef, 81.20.Ka, 82.33.Vx, 82.40.Fp, 89.20.Bb


ЦИТИРОВАННАЯ ЛИТЕРАТУРА
  1. V. V. Danilenko, Solid State Phys., 46, No. 4: 581 (2004) (in Russian). Crossref
  2. E. A. Petrov, Detonation Synthesis of Nanomaterials. Nanodiamonds and Nanotechnologies (Biysk: Altai STU: 2015) (in Russian).
  3. N. Roy. Greiner, D. S. Phillips, J. D. Johnson, and F. Volk, Nature, No. 333: 440 (1988). Crossref
  4. P. S. De Carly and I. L. Jamieson, Science, 133, Iss. 3467: 1821 (1961). Crossref
  5. G. A. Adadurov, A. V. Baluev, O. N. Breusov, V. N. Drobyshev, A. I. Rogacheva, A. M. Sapegin, and V. F. Tatsiy, Bulletin of AS USSR. Inorganic Materials, 4: 649 (1977) (in Russian).
  6. V. V. Sobolev, S. I. Gubenko, D. V. Rudakov., O. L. Kyrychenko, and O. O. Balakin, Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu, 4: 53 (2020). Crossref
  7. V. V. Sobolev, R. P. Didik, V. Ya. Slobodskoi, Y. I.Merezko, and A. I. Skidanenko, Combustion, Explosion, and Shock Waves, 19, No. 5: 658 (1983). Crossref
  8. V. V. Sobolev, O. S. Kovrov, M. M. Nalisko, N. V. Bilan, and O. A. Tereshkova, Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu, 4: 47 (2021). Crossref
  9. A. V. Kurdyumov and A. N. Pilyankevich, Phase Transformations in Carbon and Boron Nitride (Kiev: Naukova Dumka: 1979) (in Russian).
  10. V. V. Yakushev, A. N. Zhukov, A. V. Utkin, A. I. Rogacheva, and V. A. Kudakina, Combustion and Eexplosion Physics, 51, No. 5: 104 (2015). Crossref
  11. A. N. Zhukov, S. E. Zakiev, and V. V. Yakushev, High Temperature Thermophysics, 54, No. 1: 51 (2016) (in Russian). Crossref
  12. V. V. Sobolev, R. P. Didyk, V. Ya. Slobodskoy, V. P. Baraban, S. N. Selyukov, A. I. Skidanenko, and A. A. Udoev, Mineralogical Collection of Lvov University, 39, No. 2: 75 (1985) (in Russian).
  13. Z. Wang, Y. Zhao, K. Tait, X. Liao, D. Schiferl, C. Zha, T. Downs, J. Qian, Y. Zhu, and T. Shen, Proc. Natl. Acad. Sci. U. S. A., 101, No. 38: 13699 (2004). Crossref
  14. V. V. Sobolev, V. Ya. Slobodskoi, S. N. Selyukov, and A. A. Udoev, Int. Geol. Rev., 28, No. 6: 680 (1986). Crossref
  15. R. V. Eliseev, Bulletin of the KrNU named after Mikhail Ostrogradsky, 2, Iss. 73: 74 (2021) (in Ukraine).
  16. A. A. Deribas, Physics of Hardening and Explosive Welding (Novosibirsk: Nauka: 1980) (in Russian).
  17. A. V. Krupin, V. Ya. Soloviev, N. I. Sheftel, and A. G. Kobelev, Deformation of Metals by Explosions (Moskva: Metallurgiya, 1975) (in Russian).
  18. E. A. Kozlov, M. A. Lebedev, and B. V. Litvinov, Combustion and ExplosionPhysics, 2: 118 (1993) (in Russian).
  19. L. V. Altshuler, Advances of Physical Sciences, 65, No. 5: 197 (1965) (in Russian).
  20. R. F. Trunin, Properties of Condensed Substances at High Pressures and Temperatures (Sarov: RFNC FNIIEF: 1992) (in Russian).
  21. M. V. Zhernokletov, Methods for Studying the Properties of Materials under Intense Dynamic Loads (Sarov: RFNC VNIIEF: 2005) (in Russian).
  22. V. V. Danilenko, Explosion: Physics, Techniques, Technology (Moscow: Ehnergoatomizdat: 2010) (in Russian).
  23. G. I. Kanel, V. E. Fortov, and S. V. Razorenov, Advances of Physical Sciences, 177, No. 8: 809 (2007) (in Russian).
  24. P. Caldirola and H. Knoepfel, Physics of High Energy Densities (Moskva: Mir: 1974) (Russian translation).
  25. S. G. Andreev, M. M. Boyko, and V. V. Selivanov, Experimental Methods of Explosion and Impact Physics (Moskva: Fizmatlit: 2013) (in Russian).
  26. G. Ben-Dor, O. Igra and T. Elperin, Handbook of Shock Waves. Vol. 2 (San Diego: Academic Press: 2001).
  27. V. E. Mineev, Research on the Theory of Plates and Shells. Kazan: KGU, Nos. 67: 596 (1970) (in Russian).
  28. A. V. Karmishin, E. D. Skurlatov, and V. G. Startsev, Nonstationary Aeroelasticity of Thin-Walled Structures (Moskva: Mashinostroyenie: 1982) (in Russian).
  29. A. V. Chernai, V. V. Sobolev, V. A. Chernai, M. A. Ilyushin, and A. Dlugashek, Combustion and Explosion Physics, 39, No. 3: 105 (2003). Crossref
  30. V. V. Sobolev, A. V. Chernai, and M. A. Ilyushin, Chemical Physics of Combustion and Explosion Processes, 1, No. 1: 80 (Chernogolovka: CHIF RAN: 1996) (in Russian).
  31. A. V. Chernai, V. V. Sobolev, M. A. Ilyushin, V. A. Chernai, and A. D. Sharabura, High Pressure Physics and Technology, 11, No. 3: 94 (2001) (in Russian).
  32. M. A. Ilyushin, I. V. Tselinskii, and A. M. Sudarikov, Development of Components for High-Energy Compositions (St. Petersburg: Leningrad State University named after A. S. Pushkin: 2006) (in Russian).
  33. V. V. Sobolev, A. V. Chernai, and N. M. Studinskii, High-Energy Processing of Materials, 1: 136 (Dnepropetrovsk: SMAU: 1995) (in Russian).
  34. M. A. Ilyushin, I. V. Tselinsky, and I. V. Shugalei, Cent. Eur. J. Energ. Mater., 9, No. 4: 293 (2012).
  35. M. A. Ilyushin, I. V. Tselinskii, I. A. Ugryumov, A. Yu. Zhilin, and A. V. Chernai, Collection of Scientific Papers. NMAU, 18: 8 (2003) (in Russian).
  36. M. A. Ilyushin, I. V. Tselinskii, I. V. Shugalei, and A. V. Chernai, Pulse Processing of Materials (Dnepropetrovsk: NMU: 2005) (in Russian).
  37. M. A. Ilyushin, I. V. Tselinskii, A. A. Kotomin, and Yu. A. Danilov, Energy Saturated Substances of Initiation Means (St. Petersburg: Leningrad State University named after A. S. Pushkin: 2013) (in Russian).
  38. M. A. Ilyushin, A. V. Smirnov, and A. M. Sudarikov, Metal Complexes in High-Energy Compositions (St. Petersburg: Leningrad State University named after A. S. Pushkin: 2010) (in Russian).
  39. A. V. Chernai, V. V. Sobolev, V. A. Chernaj, M. A. Ilyushin, and A. Dlugashek, Combustion, Explosion and Shock Waves, 39, No. 3: 335 (2003). Crossref
  40. A. L. Kirichenko, V. V. Kulivar, and V. V. Sobolev, Bulletin of Donetsk Mining Institute, 2: 141(2017) (in Russian).
  41. V. V. Sobolev and V. V. Kulivar, III International Scientific and Practical Conference ‘Society and Science. Problems and Prospects’ (January 2528, 2022, London, England).
  42. V. V. Sobolev, L. N. Shiman, N. N. Nalisko, and A. L. Kirichenko, Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu, 6: 53 (2017) (in Russian).
  43. A. V. Chernaj, V. V. Sobolev, M. A. Ilyushin, N. E. Zhitnik, Fizika Goreniya i Vzryva, 30, No. 2: 106 (1994) (in Russian). Crossref
  44. A. V. Chernai, V. V. Sobolev, V. A. Chernai, A. Dlugasek, D. Berezovsky, and M. A. Ilyushin, Collection of Scientific Papers. NMAU, High-Energy Processing of Materials, 8: 214 (Dnepropetrovsk: Sich: 1999) (in Russian).
  45. K. P. Stanyukovich, Unsteady Motions of a Continuous Medium (Moskva: Nauka: 1971) (in Russian).
  46. Ya. B. Zeldovich and Yu. P. Raiser, Physics of Shock Waves and High-Temperature Hydrodynamic Phenomena (Moskva: Nauka: 1966) (in Russian).
  47. A. N. Afanasenkov, Blasting Work, 75/32 (Moskva: Nedra: 1975) (in Russian).
  48. A. N. Dryomin, S. D. Savrov, V. S. Trofimov, and K. K. Shvedov, Detonation Waves in Condensed Media (Moskva: Nauka: 1970) (in Russian).
  49. F. A. Baum, A. P. Orlenko, K. P. Stanyukovich, V. P. Chelyshev, and B. I. Shekhter, Physics of Explosion (Moskva: Nauka: 1975) (in Russian).
  50. A. V. Chernai, V. V. Sobolev, V. A. Chernai, M. A. Ilyushin, and Yu. P. Bunchuk, Physics of Pulse Processing of Materials (Dnipropetrovsk: ART-PRESS: 2003) (in Russian).
  51. F. Bowden and A. Ioffe, Fast Reactions in Solids (Moskva: Foreign Literature: 1962) (in Russian).
  52. L. T. Sedov, Similarity and Dimension Methods in Mechanics (Moskva: Nauka: 1987) (in Russian).
  53. R. Cole, Underwater Explosions (Moskva: Foreign Literature: 1950) (in Russian).
  54. D. Keller and J. Penning, Synthesis Microstructure and Explosive Properties of Spray-Deposited Silver Acetylide-Silver Nitrate Composite Light Initiated High Explosives (Albuquerque, NM, USA: Sandia National Laboratories: 1965).
  55. D. V. Keller and J. R. Penning, Exploding Wires, 2: 263 (1962). Crossref
  56. T. T. Covert and M. A. Chavez, Synthesis Microstructure and Explosive Properties of Spray-Deposited Silver Acetylide-Silver Nitrate Composite Light Initiated High Explosives (Albuquerque, NM, USA: Sandia National Laboratories: 2013).
  57. S. Silverman, Tech. Report, No. 1, Project No. 02-1770 (IR) (San Antonio, Texas: Southwest Research Institute: December 1965).
  58. F. O. Hoese, C. G. Angner, and W. E. Baker, Exp. Mech., 8: 392 (1968). Crossref
  59. D. Wang, J. Li, Yu. Zhang, H. Li, and S. Wang, Materials, 15, No. 12: 4100 (2022). Crossref
  60. N. P. Khokhlov, N. A. Ponkin, I. A. Lukyanenko, A. V. Rudnev, O. M. Lukovkin, Y. V. Sheikov, and S. M. Batyanov, Combust. Explos. Shock Waves, 57, No. 3: 364 (2021). Crossref
  61. T. W. Myers, K. E. Brown, D. E. Chavez, R. J. Schaarff, and J. M. Veauthier, Inorg. Chem., 56, No. 4: 2297 (2017). Crossref
  62. V. Y. Wurzenberger, M. S. Gruhne, M. Lommel, and J. Stierstorfer, Propellants Explos. Pyrotech., 46: 207 (2021). Crossref
  63. A. F. Chumak, A. D. Vlasov, and L. I. Muravina, Combustion and Explosion Physics, 13, No. 4: 650 (1977).
  64. A. V. Chernai and V. V. Sobolev, Fizika i Khimiya Obrabotki Materialov, No. 5: 120 (1995) (in Russian).
  65. A. V. Chernai, V. V. Sobolev, N. M. Studinskii, and I. L. Gumenik, Metallurgical and Mining Idustry, No. 1: 47 (1995) (in Russian).
  66. A. Chernai, V. Sobolev, and N. Nalisko, J. Scientific Israel-Technological Advantages, 18, No. 3: 98 (2016).
  67. M. Nalisko, V. Sobolev, D. Rudakov, and N. Bilan, E3S Web of Conferences 123, 01008 (Ukrainian School of Mining Engineering: 2019). Crossref
  68. L. D. Landau and E. M. Lifshitz, Continuum Mechanics (Moskva: Gostekhizdat: 1954) (in Russian).
  69. A. V. Chernai, V. V. Sobolev, M. A. Ilyushin, and N. E. Zhitnik, Combustion, Explosion, and Shock Waves, 30, No. 2: 239 (1994). Crossref
  70. A. V. Chernai, V. V. Sobolev, V. A. Chernai, M. I. Ilyushin, and A. Dlugashek, Collection of Scientific Papers. NMAU High-Energy Processing of Materials, No. 8: 221 (Dnepropetrovsk: Sich: 1999) (in Russian).
  71. A. V. Chernai, V. V. Sobolev, M. I. Ilyushin, and V. A. Mazarchenkov, Industrial Explosives and Means of their Initiation (Shostka, Sumy Region: GosNIIKhP), Iss. 1: 56 (1995) (in Russian).
  72. G. Guderley, Zylinderachse, Luftfahrtforschung, 19, No. 9: 302 (1942).
  73. Ya. B. Zeldovich, J. Exp. Theor. Phys., 36, No. 3: 783 (1959) (in Russian).
  74. R. Knystautas and J. H. Lee, Combust. Flame, 1, No. 1: 61 (1971). Crossref
  75. K. Takayama, H. Kleine, and H. Grönig, Exp. Fluids, 5: 315 (1987). Crossref
  76. A. N. Golubyatnikov, S. I. Zonenko, and G. G. Cherny, Applied Mathematics and Mechanics, 71, No. 5: 727 (2007). Crossref
  77. A. A. Makhmudov and S. P. Popov, Fluid and Gas Mechanics, 2: 167 (1980) (in Russian).
  78. E. I. Zababakhin and V. A. Simonenko, Applied Mathematics and Mechanics, 29, No. 2: 334 (1965) (in Russian). Crossref
  79. A. N. Golubyatnikov, S. I. Zonenko, and G. G. Cherny, Adv. Mech., 3, No. 1: 31 (2005) (in Russian).
  80. S. I. Zonenko and G. G. Cherny, Reports of the Academy of Sciences, 390, No. 1: 46 (2003) (in Russian).
  81. V. V. Sobolev, O. V. Skobenko, I. I. Usyk, V. V. Kulivar, and A. V. Kurliak, Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu, 6: 49 (2021). Crossref
  82. V. V. Sobolev, D. V. Rudakov, A. S. Baskevich, and A. L. Kirichenko, Physical and Mathematical Models in Problems of Laser Lnitiation of Explosives (Kyiv: SP Burya E. D.: 2020) (in Russian).