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Compression of gas bubble with inertial coating

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Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
The compression problem of the polytropic gas bubble coated by the layer of an ideal incompressible liquid has been solved in the closed form. The simple algebraic formulae, which determine the velocity and pressure fields in the liquid layer, as well as the critical (minimal) radius of the maximally compressed bubble, have been derived. The adiabatic and isothermal gas compressions were examined. The time of the compression process was determined. The general solution of the problem was achieved. The solutions, known in the literature of the similar but simplified problems, result from our solution as particular cases.
Rocznik
Strony
3--17
Opis fizyczny
Bibliogr. 31 poz., wykr.
Twórcy
  • Military University of Technology, Faculty of Armament and Aviation Technology, S. Kaliskiego 2, 00-961 Warsaw, Poland
Bibliografia
  • 1. I.J. CAMPBELL, Note on sound propagation in gas-liquid mixture, Admiralty Research Laboratory, Report A.R.L./NI/G/NY/17/0. Teddington, Middlesex, England, 1957.
  • 2. I.J. CAMPBELL, Normal impact of a plane shock on the interface between a liquid and a gas - liquid mixture, Admiralty Research Laboratory, Report A.R.L./N2/G/NY/17/0. Teddington, Middlesex, England, May 1958.
  • 3. I.J. CAMPBELL, A.G. PITCHER, Shock waves in a liquid containing gas bubbles, Proc. Roy. Soc., A 234, 1235, 1958.
  • 4. B.R. PARKIN, F.R. GILMORE, H.L. BRODE, Shock waves in bubbly water, Memorandum RM- 2795-PR (abridged), October 1961.
  • 5. M.M. CHAUDRI, J.E. FIELD, The role of rapidly compressed gas pockets in the initiation of condensed explosives, Proc. Roy. Soc. London., A 340, 1974.
  • 6. R. HICKLING, M.S. PLESSET, Collapse and rebound of a spherical bubble in water, The Physics of Fluids, 7, 1, 1964.
  • 7. C. MADER, Shock and hot spot initiation of homogeneous explosives, Phys. Fluids, 6, 3, 1963.
  • 8. E. WŁODARCZYK, The role of gas bubbles in the initiation detonation of slurry explosives (SE) [in Polish], Biul. WAT, XXXIV, 3, 1985.
  • 9. E. WŁODARCZYK, Analysis of the efficiency of initiation of a detonation by “hot spots” generated by shock compression of gas bubbles included in the explosive. Part I. Analysis of the experimental data, J. Tech. Phys., 33, 1, 1992. Part II. Theoretical analysis, J. Tech. Phys., 33, 2, 1992.
  • 10. W. TRZCIŃSKI, E. WŁODARCZYK, Compression of a spherical gas bubble in ideal liquid by the finite pressure-pulse, J. Tech. Phys., 22, 4, 1981.
  • 11. W. TRZCIŃSKI, E. WŁODARCZYK, On adiabatic compression of gas bubbles in noncompressible viscous liquid, J. Tech. Phys., 22, 3, 1981.
  • 12. W. TRZCIŃSKI, E. WŁODARCZYK, Shock compression of gas bubbles in ideal compressible liquid, J. Tech. Phys., 22, 3, 1981.
  • 13. W. TRZCIŃSKI, E. WŁODARCZYK, Adiabatic compression of a van der Waals gas bubble in liquid, J. Tech. Phys., 24, 3, 1983.
  • 14. JE. U. ZABABAKHIN, Collapse of bubbles in a viscous liquid [in Russian], PMM, 24, 4, 1960.
  • 15. N.A. GRIGORIEV, G.S. DORONIN, V.L. ODINOKIJ, Action of a pressure impulse on a cavity in a viscous liquid [in Russian], PMTF, 2, 1978.
  • 16. Y. TOMITA, A. SHIMA, On the behavior of a spherical bubble and the impulse pressure in a viscous compressible liquid, Bulletin of the JSME, 20, 149, 1977.
  • 17. E. WŁODARCZYK, Fundamentals of the explosion mechanics [in Polish], PWN, Warszawa 1994.
  • 18. A. JACKOWSKI, E. WŁODARCZYK, Theoretical assessment of a influence of the sintered liner porosity on hydrodynamic parameters in the collision zone of colliding liner elements [in Polish], Biul. WAT, XLVI, 4, 1997.
  • 19. R. TRĘBIŃSKI, W. URBANIAK, J. PASZULA, Experimental studies of the gas pores influence on the effects of the iron powder explosive compaction [in Polish], Biul. WAT, XLV, 6, 1996.
  • 20. R. TRĘBIŃSKI, W. URBANIAK, Theoretical analysis of the gas pores influence on the effects on the powders explosive compaction [in Polish], Biul. WAT, XLV, 6, 1996.
  • 21. M.M. CAROLL, A.C. HOLT, Static and dynamic pore-collapse relations for ductile porous materials, J. Appl. Phys., 43, 4, 1972.
  • 22. B.M. BUTCHER, M.M. CAROLL, A.C. HOLT, Shock-wave compaction of porous aluminium, J. Appl. Phys., 45, 9, 1974.
  • 23. S.Z. DUNIN, V.V. SURKOV, Dynamics of the pores collapse into shock wave front [in Russian], PMM, 43, 3, 1979.
  • 24. V.G. GRIGORIEV, S.Z. DUNIN, V.V. SURKOV, Collapse of the spherical pore in a viscoplastic medium [in Russian], MTT, 1, 1981.
  • 25. A.V. ATIENKOV, A.J. VLASOWA, V.V. SIELIVANOV, V.S. SOLOVIEV, Influence of the unbalance heating on the behaviour of a porous medium at an impact compression [in Russian], Zh PMTF, 6, 1984.
  • 26. A.V. ATIENKOV, A.J. VLASOVA, V.V. SIELIVANOV, V.S. SOLOVIEV, Local medium heating in a neighbourhood of a pore at its collapse [in Russian], ZhPMTF, 2, 1984.
  • 27. L.V. ALTSHULER, Application of shock waves in high pressure physics [in Russian], UFN, 85, 2, 1965.
  • 28. G.M. LYAKHOV, Fundamentals of the explosive dynamics in soils and liquid media [in Russian], Niedra, Moskva 1964.
  • 29. YA.B. ZIELDOVICH, YU.P. RAUZER, Shock waves physics and of high-temperature hydrodynamic phenomena [in Russian], Nauka, Moskva 1966.
  • 30. E. WŁODARCZYK, Fundamentals of detonation [in Polish], WAT, 1995.
  • 31. J.W. RAYLEIGH, Phys. Mag., 34, 1917, 94.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-article-BAT5-0002-0028
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