Elastic‐wave stimulation of oil production: A review of methods and results

Beresnev, Igor A.; Johnson, Paul A.

doi:10.1190/1.1443645

Cited by 288 publications

(186 citation statements)

References 22 publications

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“…Since the concept of dynamic permeability was proposed several years ago [1,2], it has been extensively used in the study of practical problems such as petroleum recovery [3], soil-ground water transport [4], fluids flowing in porous media [5,6], acoustic waves in porous media [7], wave propagation in foams [8], fluid circulation in biological systems [9], etc. The use of the dynamic permeability as originally proposed [1] however, is not quite correct for some of these systems since the fluid does not behave as a Newtonian fluid but shows viscoelastic features.…”

Section: Introductionmentioning

confidence: 99%

Experimental observation of dramatic differences in the dynamic response of Newtonian and Maxwellian fluids

Castrejón‐Pita¹,

Río²,

Castrejón‐Pita³

et al. 2003

Phys. Rev. E

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An experimental study of the dynamic response of a Newtonian fluid and a Maxwellian fluid under an oscillating pressure gradient is presented. Laser Doppler anemometry is used in order to determine the velocity of the fluid inside a cylindrical tube. In the case of the Newtonian fluid, the dissipative nature is observed. In the dynamic response of the Maxwellian fluid an enhancement at the frequencies predicted by theory is observed.

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Section: Introductionmentioning

confidence: 99%

Experimental observation of dramatic differences in the dynamic response of Newtonian and Maxwellian fluids

Castrejón‐Pita¹,

Río²,

Castrejón‐Pita³

et al. 2003

Phys. Rev. E

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“…It has also been observed in some laboratory measurements and field applications that imposing harmonic signals into cores or reservoirs sometimes may induce higher fluid flow rates (Pan and Horne 2000). Further the fact that the pore pressure may undergo variations under the influence of seismic waves is well known to geotechnical engineers (Beresnev and Johnson 1994). In addition, laboratory experiments have shown that ultrasonic radiation can considerably increase the rate of flow of a liquid through a porous medium (Aarts and Ooms 1998).…”

Section: Introductionmentioning

confidence: 98%

Monte Carlo Assessment of the Impact of Oscillatory and Pulsating Boundary Conditions on the Flow Through Porous Media

Rahrah

Vermolen

2018

Transp Porous Med

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Stress and water injection induce deformations and changes in pore pressure in the soil. The interaction between the mechanical deformations and the flow of water induces a change in porosity and permeability, which results in nonlinearity. To investigate this interaction and the impact of mechanical vibrations and pressure pulses on the flow rate through the pores of a porous medium under a pressure gradient, a poroelastic model is proposed. In this paper, a Galerkin finite element method is applied for solving the quasi-static Biot's consolidation problem for poroelasticity, considering nonlinear permeability. Space discretisation using Taylor-Hood elements is considered, and the implicit Euler scheme for time stepping is used. Furthermore, Monte Carlo simulations are performed to quantify the impact of variation in the parameters on the model output. Numerical results show that pressure pulses and soil vibrations in the direction of the flow increase the amount of water that can be injected into a deformable fluid-saturated porous medium.

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“…Biot theoretically studied this phenomenon by considering the flow of a viscous fluid in a tube with longitudinally oscillating walls under an oscillatory pressure gradient. Apart from the fundamental interest, the investigation of the dynamics of fluid in porous media under oscillatory pressure gradient and oscillating pore walls is of prime importance for the recently emerged technology of acoustic stimulation of oil reservoirs [2]. For example, it is known that the natural pressure in an oil reservoir generally yields no more than approximately 10 percent oil recovery.…”

Section: Introductionmentioning

confidence: 99%

Enhancement in the dynamic response of a viscoelastic fluid flowing through a longitudinally vibrating tube

Tsiklauri

Beresnev

2001

Phys. Rev. E

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We analyzed effects of elasticity on the dynamics of fluids in porous media by studying a flow of a Maxwell fluid in a tube, which oscillates longitudinally and is subject to oscillatory pressure gradient. The present study investigates novelties brought about into the classic Biot's theory of propagation of elastic waves in a fluid-saturated porous solid by inclusion of non-Newtonian effects that are important, for example, for hydrocarbons. Using the time Fourier transform and transforming the problem into the frequency domain, we calculated: (A) the dynamic permeability and (B) the function F (κ) that measures the deviation from Poiseuille flow friction as a function of frequency parameter κ. This provides a more complete theory of flow of Maxwell fluid through the longitudinally oscillating cylindrical tube with the oscillating pressure gradient, which has important practical applications. This study has clearly shown transition from dissipative to elastic regime in which sharp enhancements (resonances) of the flow are found.

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Elastic‐wave stimulation of oil production: A review of methods and results

Cited by 288 publications

References 22 publications

Experimental observation of dramatic differences in the dynamic response of Newtonian and Maxwellian fluids

Experimental observation of dramatic differences in the dynamic response of Newtonian and Maxwellian fluids

Monte Carlo Assessment of the Impact of Oscillatory and Pulsating Boundary Conditions on the Flow Through Porous Media

Enhancement in the dynamic response of a viscoelastic fluid flowing through a longitudinally vibrating tube

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