Dynamic Gas Slippage: A Unique Dual-Mechanism Approach to the Flow of Gas in Tight Formations

Ertekin, Turgay; King, Gary; Schwerer, F. C.

doi:10.2118/12045-pa

Cited by 276 publications

(141 citation statements)

References 6 publications

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“…Based on flow mechanisms in coal matrixs, the flow velocity is dominated by both the pressure gradient and the concentration gradient. Referencing the research result of Ertekin et al [28], the velocity in the matrix can be added by the velocity of the pressure gradient and the concentration gradient linearly, which can be expressed as:…”

Section: Model Constructionmentioning

confidence: 99%

Production decline type curves analysis of a finite conductivity fractured well in coalbed methane reservoirs

Wei

Wen²,

Duan

et al. 2017

Open Physics

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Production decline type curves analysis is one of the robust methods used to analyze transport flow behaviors and to evaluate reservoir properties, original gas in place, etc. Although advanced production decline analysis methods for several well types in conventional reservoirs are widely used, there are few models of production decline type curves for a fractured well in coalbed methane (CBM) reservoirs. In this work, a novel pseudo state diffusion and convection model is firstly developed to describe CBM transport in matrix systems. Subsequently, based on the Langmuir adsorption isotherm, pseudo state diffusion and convection in matrix systems and Darcy flow in cleat systems, the production model of a CBM well with a finite conductivity fracture is derived and solved by Laplace transform. Advanced production decline type curves of a fractured well in CBM reservoirs are plotted through the Stehfest numerical inversion algorithm and computer programming. Six flow regimes, including linear flow regime, early radial flow in cleat systems, interporosity flow regime, late pseudo radial flow regime, transient regime and boundary dominated flow regime, are recognized. Finally, the effect of relevant parameters, including the storage coefficient of gas in cleat systems, the transfer coefficient from a matrix system to the cleat system, the modified coefficient of permeability, dimensionless fracture conductivity and dimensionless reservoir drainage radius, are analyzed on type curves. This paper does not only enrich the production decline type

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Section: Model Constructionmentioning

confidence: 99%

Production decline type curves analysis of a finite conductivity fractured well in coalbed methane reservoirs

Wei

Wen²,

Duan

et al. 2017

Open Physics

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“…Other models based on capillary tubes are described (Bear, 1972;Kanellopoulos, 1985). Ertekin et al (1986) incorporated Klinkenberg's slippage effect to account for the higher than predicted value of production in shale reservoirs. Javadpour (2009) stated that both slippage and Knudsen diffusion become important at the shale nano pore scale.…”

Section: Shale Gas Flow Mechanism In Capillarymentioning

confidence: 99%

“…The gas flowing model that considers pore size has been applied to shale gas reservoir; it considers the change in the state of gas molecules according to Darcy's law. The Klinkenberg slippage effect contributes to the analysis of the production increase of tight gas and shale gas reservoirs (Ertekin et al, 1986). A comprehensive slippage concept is used to modify Darcy's law (Clarkson et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

Shale Gas Pseudo Two-Dimensional Unsteady Seepage Pressure Simulation Analysis in Capillary Model

Lai

et al. 2014

Oil Gas Sci. Technol. – Rev. IFP Energies nouvelles

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-Shale gas is rapidly growing as a source of natural gas in China. Compared with the conventional gas reservoir, the shale gas reservoir is characterized by low porosity, low permeability, and adsorbed gas, making the flow mechanism of shale gas reservoir more complex. In this study, we investigated six factors influencing the gas flow: the Darcy flow, the slippage effect, the Knudsen diffusion effect, the desorption of gas on pore walls, the diffusion effect of gas in organic matter, and the matrix deformation effect. We simplified gas flow in the development process to only include gas flow in the capillaries and then considered the six influence factors. This study establishes a shale gas pseudo two-dimensional unsteady capillary seepage mathematical model based on the continuity equation, using the implicit difference method to solve the mathematical model. Certain capillary parameters were added to the calculation, and the study analyzed the effect of the different factors on both the pressure distribution and the cumulative gas production. Results show that the Knudsen diffusion effect and the desorption of gas from pore walls have lower impact on the pressure than the others factors. The diffusion effect of gas in organic matter, the slippage effect, and the matrix deformation effect have a stronger impact on the pressure. The gas in organic matter continuously diffuses into the capillary with the increasing of the production time, and the pressure drop becomes slow because of the gas diffusion.Re´sume´-Analyse des instabilite´s d'une simulation pseudo-bidimensionnelle de la pression de filtration de gaz de schiste dans un mode`le capillaire -Le gaz de schiste connaıˆt une croissance rapide en tant que source de gaz naturel en Chine. En comparaison du re´servoir de gaz conventionnel, le re´servoir de gaz de schiste se caracte´rise par une faible porosite´, une faible perme´abilite´, et par le gaz adsorbe´qui rend le me´canisme d'e´coulement du re´servoir de gaz de schiste plus complexe. Dans cette e´tude, nous avons e´tudie´six facteurs qui influencent le de´bit de gaz : l'e´coulement selon le mode`le de Darcy, l'effet de glissement, l'effet de diffusion Knudsen, la de´sorption du gaz sur les parois poreuses, l'effet de diffusion du gaz dans la matie`re organique et l'effet de de´formation de la matrice. Nous avons simplifie´le de´bit de gaz dans un mode`le pour inclure uniquement le de´bit de gaz dans les capillaires et ensuite e´tudier les six facteurs d'influence. Cette e´tude de´veloppe un mode`le mathe´matique de pe´ne´tration capillaire instable et pseudo-bidimensionnelle du gaz de schiste en se fondant sur l'e´quation de continuiteé t en utilisant la me´thode de diffe´rence implicite pour re´soudre le mode`le mathe´matique.

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“…An example of such situation is flow of gas in a tight reservoir with extremely small pores [23] 1 . The threshold between diffusive and classical flow regimes suggested in the literature [7] is between Kn ∼ 10 −3 and Kn ∼ 10 −2 .…”

Section: Steady Flow Of Incompressible Viscous Fluidmentioning

confidence: 99%

Digital Rock Studies of Tight Porous Media

Silin¹

2012

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Abstract. This technical report summarizes some recently developed approaches to studies of rock properties at a pore scale. Digital rock approach is complementary to laboratory and field studies. It can be especially helpful in situations where experimental data are uncertain, or are difficult or impossible to obtain. Digitized binary images of the pore geometries of natural rocks obtained by different imaging techniques are the input data. Computer-generated models of natural rocks can be used instead of images in a case where microtomography data are unavailable, or the resolution of the tools is insufficient to adequately characterize the features of interest. Simulations of creeping viscous flow in pores produce estimates of Darcy permeability. Maximal Inscribed Spheres calculations estimate two-phase fluid distribution in capillary equilibrium. A combination of both produce relative permeability curves. Computer-generated rock models were employed to study two-phase properties of fractured rocks, or tight sands with slit-like pores, too narrow to be characterized with micro-tomography. Various scenarios can simulate different fluid displacement mechanisms, from piston-like drainage to liquid dropout at the dew point.A finite differences discretization of Stokes equation is developed to simulate flow in the pore space of natural rocks. The numerical schemes are capable to handle both no-slip and slippage flows. An upscaling procedure estimates the permeability by subsampling a large data set. Capillary equilibrium and capillary pressure curves are efficiently estimated with the method of maximal inscribed spheres both an arbitrary contact angle. The algorithms can handle gigobytes of data on a desktop workstation. Customized QuickHull algorithms model natural rocks. Capillary pressure curves evaluated from computer-generated images mimic those obtained for microtomography data.

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Dynamic Gas Slippage: A Unique Dual-Mechanism Approach to the Flow of Gas in Tight Formations

Cited by 276 publications

References 6 publications

Production decline type curves analysis of a finite conductivity fractured well in coalbed methane reservoirs

Production decline type curves analysis of a finite conductivity fractured well in coalbed methane reservoirs

Shale Gas Pseudo Two-Dimensional Unsteady Seepage Pressure Simulation Analysis in Capillary Model

Digital Rock Studies of Tight Porous Media

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