Abstract—
As fluids and gases move through porous media, they generate acoustic noise. It is shown that the shape of the noise spectra is determined by the properties of the fluid and the porous reservoir, as well as by the flow regime. Our study has experimentally confirmed the conclusions that the location of sound intensity maxima are independent of the rate of fluid filtration through a porous medium. The criterion for the occurrence of filtration noise as a fluid moves through a porous medium is determined. The dependence of the sound intensity maximum on the fluid filtration rate is studied. The relationship between the porosity and permeability of porous media samples and the character of the filtration noise spectra is considered. The obtained experimental data can be used to create a sound generation model for gas filtration through a porous medium.
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REFERENCES
L. D. Gik, Fiz. Mezomekh., No. 4, 67 (2008).
Yu. I. Kuznetsov, Karotazhnik, No. 2 (272), 95 (2017).
V. V. Dryagin, D. B. Ivanov, I. A. Chernykh, and A. V. Shumilov, Karotazhnik, No. 10 (244), 57 (2014).
E. F. Afanas’ev, K. L. Grdzelova, and D. V. Plyushchev, Dokl. Akad. Nauk SSSR, No. 3, 554 (1987).
M. N. Ovchinnikov, F. F. Karimov, and A. S. Nikolaev, Georesursy, No. 1, 31 (2001).
A. I. Ipatov, A. V. Gorodnov, L. P. Petrov, A. E. Shumeiko, and S. P. Skopintsev, Karotazhnik, No. 9 (122), 51 (2004).
A. I. Ipatov, A. V. Gorodnov, S. I. Ipatov, N. N. Mar’enko, L. P. Petrov, and S. P. Skopintsev, Geofisika, No. 2, 25 (2004).
D. A. DiCarlo, J. I. G. Cidoncha, and C. Hickey, Geophys. Res. Lett. 30 (17) (2003). https://doi.org/10.1029/2003GL017811
E. A. Ivanova and D. N. Mikhailov, Uch. Zap. Fiz. Fak. Mosk. Univ., No. 5, 1750805 (2017).
V. V. Dryagin, Acoust. Phys. 59 (6), 694 (2013).
A. V. Lavrov and V. L. Shkuratnik, Acoust. Phys. 51 (1 Suppl.), S2 (2005).
D. N. Mikhailov and V. N. Nikolaevskii, Fluid Dyn. 35 (5), 715 (2000).
GOST (State Standard) No. 26450.1-85: Rocks. Method for Determination of Open Porosity Coefficient by Fluid Saturation (Izd. Standartov, Moscow, 1986).
GOST (State Standard) No. 26450.2-85: Rocks. Method for Determination of Absolute Gas Permeability Coefficient by Stationary and Non-Stationary Filtration (Izd. Standartov, Moscow, 1985).
GOST (State Standard) No. 12536-2014: Soils. Methods of Laboratory Granulometric (Grain-Size) and Microaggregate Distribution (Izd. Standartov, Moscow, 2015).
E. A. Marfin, I. S. Metelev, B. A. Garif’yanov, and A. A. Abdrashitov, Uch. Zap. Fiz. Fak. Mosk. Univ., No. 6, 146316 (2014).
E. A. Marfin, T. A. Kirpichnikova, and I. S. Metelev, Uch. Zap. Fiz. Fak. Mosk. Univ., No. 5, 1751407 (2017).
T. D. Van Golf-Racht, Fundamentals of Fractured Reservoir Engineering (Elsevier Scientific, Amsterdam, Oxford, New York, 1982; Nedra, Moscow, 1986).
V. S. Basniev, N. M. Dmitriev, and G. D. Rozenberg, Oil-and-Gas Hydromechanics (Institut Komp’uternykh Issledovanii, Moscow-Izhevsk, 2005) [in Russian].
K. S. Basniev, N. M. Dmitriev, R. D. Kanevskaya, and V. M. Maksimov, Subsurface Hydromechanics (Institut Komp’uternykh Issledovanii, Moscow, 2006) [in Russian].
S. I. Sergeev, N. I. Ryzhikov, and D. N. Mikhailov, in Proc. Int. Conference “Saint Petersburg 2018: Innovations in Geosciences, Time for Breakthrough” (Saint Petersburg, 2018). https://doi.org/10.3997/2214-4609.20180030 https://doi.org/10.3997/2214-4609.20180030
V. N. Shchelkachev and B. B. Lapuk, Subsurface Hydraulics (Gostoptekhizdat, Moscow, 1949) [in Russian].
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Metelev, I.S., Ovchinnikov, M.N., Marfin, E.A. et al. Study of Acoustic Noise during Gas Filtration through a Porous Medium. Acoust. Phys. 65, 200–207 (2019). https://doi.org/10.1134/S1063771019020088
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DOI: https://doi.org/10.1134/S1063771019020088