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Tytuł artykułu

The laboratory modelling of effects of electric and acoustic fields interaction in porous media saturated with water of hydrocarbons

Autorzy
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
The results of experimental studies of electric resistivity of free electrolytes, oils, and models of saturated rocks in an ultrasonic field are presented. It is shown that the resistivity of electrolytes varies rather insignificantly compar-ing to that of oil subject to elastic energy. A theoretical model to explain the obtained experimental results is proposed. The formulae derived offer a possibility to calculate changes of electric resistivity of oil in a wide spectrum of ultrasonic vibration intensities, and to make quantitative evaluation of the mechanoelectric effect, very useful in laboratory and borehole investigations of properties of rocks saturated with hydrocarbons or water. The obtained results suggest possibilities of inventing new methods in geophysical prospecting.
Rocznik
Strony
381--396
Opis fizyczny
Bibliogr. 26 poz.
Twórcy
autor
  • Institute of Geological Sciences, Department of Structural Geology, University of Wrocław, ul. Cybulskiego 32, 30-205 Wrocław
Bibliografia
  • 1. Bartolomey, N., and Y. Kolombo, 1980, Main Aspects of Oil Geochemistry, Nedra, Moscow, 384 p. (in Russian).
  • 2. Bashkirov, G.L., and Yu.G. Sobotka, 1992, Methodological principles of modelling of the effects of interactions of various physical fields, Tezisy 2-go Vsesoyuzn. Soveshch. "Inzhinerno-Fizicheskie Problemy Novoy Tekhniki", Moscow, 65-66 (in Russian).
  • 3. Bergman, A., 1957, Ultrasound, Izd. Inostr. Liter. 756 p. (in Russian).
  • 4. Biot, M.S., 1956, Theory of propagation of elastic waves in a fluid-saturated porous solid, J. Acoust. Soc. Am. 28, 168-178.
  • 5. Elpirin, I.S., 1959, On the mechanism of chemical effects of ultrasonic waves, Akust. Zhurn. 2,23-31 (in Russian).
  • 6. Fenoglio, M.A., MJ.S. Johnston and J.D. Byerlee, 1995, Magnetic and electnc fields associated with changes in high pore pressure in fault zones, application to the Lorna Prieta ULF emissions, J. Geophys. Res. 100, 12951-12958.
  • 7. Fitterman, D.V., 1981, Correction to "Theory of electrokinetic-magnetic anomalies in a faulted half-space", J. Geophys. Res. 86, 9585-9588.
  • 8. Frenkel, A.I., 1944, On the theory of seismic and seismoelectrical phenomena in water-saturated rocks, Izv. Acad. Sci. USSR, Ser. Geogr. Geophys. 8, 134-150.
  • 9. Ishido, T., and H. Mizutani, 1981, Experimental and theoretical basis of electrokinetic phe¬nomena in rock-water systems and its application to geophysics, J. Geophys. Res. 86, 1763-1775.
  • 10. Ivanov, A.G., 1939, Effect of electrization of earth layers by elastic waves passing through them, Comptes Rendus de l'Academic des Sciences de l'URSS 24, 1, 42-45.
  • 11. Jossinet, J., B. Lavandier and D. Carthinol, 1998, The phenomenology of acusto-electric in-teraction signals in aąueous solution of electrolytes, Ultrasonics 36, 607-613.
  • 12. Kryachko, Y.M., V.V. Kunike and S.A. Ruslakov, 1983, Effects of acoustic field on electric conductivity of electrolytes and gas-fluid suspensions, Akust. Zhurn. 29, 3, 68-73 (in Russian).
  • 13. Landau, L.D, and E.M. Lifshitz, 1986, Theory of Elasticity, Pergamon, Oxford and New York, 187 p.
  • 14. Lavandier, B., J. Jossinet and D. Cathignol, 2000, Experimental measurement of the acousto-electric interaction signal in saline solution, Ultrasonics 38,929-936.
  • 15. Obraz, J., 1983, Ultrasounds in Measurement Technology, Wydawnictwa Naukowo-Techniczne, Warszawa, 486 p. (in Polish).
  • 16. Parkhomenko, E.I., 1971, Electrification phenomena in rocks. In: "Monographs in Geo-science", Plenum Press, New York, 285 p.
  • 17. Podsrigakh, Ya. S., Ya. I. Burak and V.F. Kondrat, 1982, Magneto-thermo-elastic interaction in electro-conductive solids, Naukova Dumka, Kiev, 296 p. (in Russian).
  • 18. Sadovskiy, M.A., M.T. Abasov and A.V. Nikolaev, 1986, Prospects for an application of the effect of vibration on the petroleum deposit for the purpose of an increase in crude-oil yield, Vestnik AN SSSR 9, 95-99 (in Russian).
  • 19. Sobolev, G.A., and V.M. Demin, 1980, Mekhano-electric Phenomena in the Earth, Nauka, Moscow, 210 p. (in Russian).
  • 20. Sobotka, Yu.G., 1992, Methods of acoustic simulation of electrophysical processes in the study of fluid-saturated rocks, Avtoreferat dissertatsyi na soiskanie uchonov stepeni kandidata geologo-min. nauk, Ivano Frankovsk, 20 p. (in Russian).
  • 21. Surguchov, M.L., 1985, Second and Third Level Methods of an Increase in Crude-oil Yield of the Layers, Nedra, Moscov, 308 p. (in Russian).
  • 22. Synayski, E.H., 1997, Hydrodynamics of Physical-Chemical Processes, Nedra, Moscow, 351 p. (in Russian).
  • 23. Thompson, A.H., and G. A. Gist, 1993, Geophysical application of electrokinetic conversion, The Leading Edge 12, 1169-1173.
  • 24. Vakhitov, G.G., and E.M. Simkin, 1985, The Use of Physical Fields in the Study of Oil, Nedra, Moscow, 232 p. (in Russian).
  • 25. Verbitskiy, T.Z., and A.S. Fedoryshyn, 1987, Mathematical modelling of rocks with the aim of predicting their physical properties, Geofiz. Zhurn. 9, 2, 39-45 (in Russian).
  • 26. Zlotnicki, J., J.P. Pozzi and F.H. Cornet, 1981, Investigation of induced magnetization variations caused by triaxial stresses, J. Geophys. Res. B12, 86, 11899-11909.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-article-BSL7-0008-0017
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