Permeability Measurement of Organic-Rich Shale - Comparison of Various Unsteady-State Methods

Jin, Guodong; Pérez, Héctor González; Dhamen, Ali Abdullah Al; Ali, Syed A.; Nair, Archana M.; Agrawal, Gaurav; Khodja, Mohamed R.; Hussaini, Syed Rizwanullah; Jangda, Zaid Zaffar; Ali, Abdulwahab

doi:10.2118/175105-ms

Cited by 12 publications

(7 citation statements)

References 20 publications

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“…Transient permeability measurement approach can be performed on crashed cores, commonly known as Gas Research Institute (GRI) method (Luffel et al, 1993;API 1998;Cui et al, 2009;Passey et al, 2010;Profice et al, 2012;Tinni et al, 2012;Heller, et al, 2014;Civan and Devegowda, 2014), or on intact cores Lin, 1977;Haskett et al, 1988;Dicker and Smith 1988;Jones 1997;Akkutlu and Fathi, 2012;Mokhtari and Tutuncu, 2015;Jin et al, 2015;Zhou et al, 2016). Unsteady state (transient) methods are the alternatives to measure micro and nano-Darcy permeability formations at a reasonably short time.…”

Section: Permeability Measurement Methodologymentioning

confidence: 99%

Experimental Investigation on Permeability and Porosity Hysteresis in Low-Permeability Formations

Teklu

Zhou

et al. 2016

SPE Low Perm Symposium

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Permeability and porosity decrease with increasing net stress in consolidated and unconsolidated porous media is a well-known phenomenon to petroleum and geomechanics engineers. Conversely, permeability and porosity are observed to increase when net stress decreases, however typically follow a different path, this discrepancy is known as hysteresis. The trend of permeability and porosity hysteresis is a signature of porous medium that depends on several physical and mechanical properties.Understanding permeability and porosity hysteresis plays a significant role in production strategies of hydrocarbon reservoirs. Hysteresis effect on production strategies can be even more important in very low permeability reservoirs such as tight sandstone, tight carbonate, and shale formations. The reason is that the stress change associated with permeability and porosity hysteresis can affect adsorption/desorption and diffusion transport mechanisms which are among the main driving mechanisms in low or ultra-low permeability reservoirs.In this study, permeability and porosity hysteresis of nano, micro, and milli-Darcy core samples are measured for a wide range of net stress and the results are correlated with pore structures observed by Field Emission Scanning Electron Microscopy (FE-SEM) images. The nano and micro-Darcy core samples are from the Niobrara, Bakken, Three Forks, and Eagle Ford formations. The milli-Darcy core samples are from Middle East carbonate, Indiana Limestone, and Torrey Buff Sandstone formations. Bakken, Three Forks, and Middle East carbonate are core samples from oil producing reservoirs, whereas others are from outcrop. Our experimental observations show that: (a) compared to steady state method, the unsteady state permeability measurement used here can shorten the time required to measure permeability of nano and micro-Darcy cores without significant measurement error; (b) stress dependency of permeability and porosity and their hysteresis during loading and unloading of outcrop cores were observed to be very small compared to those of reservoir cores; (c) generally, the stress dependency and hysteresis of permeability and porosity was observed to be inversely related permeability and porosity at initial stress conditions; hence, these characteristics are more pronounced and important in organic rich shale reservoirs; (d) porosity decrease with stress and its hysteresis were observed to be much smaller than that of permeability; (e) our results generally follow the experimental and theoretical relationship between cubic root of permeability and logarithmic of net stress reported by many researchers; and (f) an increase in permeability with temperature (and decrease in permeability with hysteresis during temperature unloading) is observed in organic rich mudrocks. This is due to dilation, diffusion, and adsorption effects of organic rich pores. Hence, a temperature correction factor is required to estimate the exact in-situ permeability of organic rich mudrocks.Finally, we would like to comment that und...

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Section: Permeability Measurement Methodologymentioning

confidence: 99%

Experimental Investigation on Permeability and Porosity Hysteresis in Low-Permeability Formations

Teklu

Zhou

et al. 2016

SPE Low Perm Symposium

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“…In both cases, the ζ potential measurements have shown to be dependent on cation type. Also, it may be logical for ζ potential measurements on solid and crushed samples to differ because both states exhibit different permeabilities, but this is of less importance because the focus is on surface chemistry and not flow transmissibility. Nonetheless, ζ potential measurement is effective in studying COBR systems: reflecting multiple surface properties, examining the influence of pH and ionic strength, , examining the presence of specific functional groups, and investigating the adsorption and desorption behavior of crude oil components on rock surfaces.…”

Section: Mechanistic Studiesmentioning

confidence: 99%

From Mineral Surfaces and Coreflood Experiments to Reservoir Implementations: Comprehensive Review of Low-Salinity Water Flooding (LSWF)

2017

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Low-salinity water flooding (LSWF) is an emerging and inexpensive enhanced oil recovery (EOR) method. The technique hinges on the following concept: as salinity of injected water reduces, additional oil is recovered. However, LSWF remains emerging because its underlying mechanisms have been largely elusive, and the identified ones have been controversial. If properly investigated, smart water injection may contribute to harnessing both heavy-oil reservoirs, which account for nearly 80% of world’s petroleum reserves, and conventional light-to-medium oil reservoirs. This report presents a comprehensive review of low-salinity water injection as an EOR method, with a specific focus on consistencies or lack of them, that occurs primarily due to inadequate understanding of oil–brine and rock–oil–brine interactions. In presenting well-documented scientific information, we expect to apprise industry and academic researchers that LSWF warrants more-advanced research based on interdisciplinary approach (bridging the gap between science and engineering) and the integration of knowledge from R&D efforts and observations from the atomic to the field scales.

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“…Third, pore pressure oscillations method was proposed in order to tackle the problem of getting noisy signal from the pulse decay technique. In this method, sinusoidal pore pressure pulse is sent from the upstream of the sample and based on the retardation of the signal and phase change at the downstream, permeability can be calculated (Fischer 1992;Jin et al 2015). However, recent pressure transducers do not cause noisy signals that require a new modification on enhancing the signal, especially when the signal is clear from a simpler measurement technique like the pulse decay.…”

Section: Introductionmentioning

confidence: 99%

Gas permeability measurements from pressure pulse decay laboratory data using pseudo-pressure and pseudo-time transformations

Abdelmalek

Karpyn

Liu

et al. 2017

J Petrol Explor Prod Technol

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This paper presents a pseudo-pressure and pseudo-time straight-line approach to interpret laboratory pulse decay data in order to estimate rock core permeability using gas as the pore fluid. The implementation of the straight-line approach provides a practical method to estimate gas permeability from experimental data, as long as changes in gas viscosity and compressibility are negligible. On the other hand, pseudo-pressure and pseudo-time allow the transformation of the compressible flow equation from its highly nonlinear form to a quasi-linear partial differential equation, where changes in gas viscosity, gas compressibility and compressibility factor are accounted for. The purpose of this work is to combine both, pseudofunctions and the straight-line approach to estimate gas permeability from pressure pulse laboratory data with a more rigorous treatment of gas properties. Five pulse decay experiments were performed in Marcellus shale cores at pore pressures ranging from 130 to 700 psi in a triaxial cell to estimate permeability and porosity of ultra-low permeability cores. The experiments were made in an increasing order of equilibration pressure starting from 130 until 700 psi, and vertical and radial stresses kept constant at 1500 psi. Permeability estimates were compared against the P 2 -approach to show the validity of the proposed method at low gas pressures.

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Permeability Measurement of Organic-Rich Shale - Comparison of Various Unsteady-State Methods

Cited by 12 publications

References 20 publications

Experimental Investigation on Permeability and Porosity Hysteresis in Low-Permeability Formations

Experimental Investigation on Permeability and Porosity Hysteresis in Low-Permeability Formations

From Mineral Surfaces and Coreflood Experiments to Reservoir Implementations: Comprehensive Review of Low-Salinity Water Flooding (LSWF)

Gas permeability measurements from pressure pulse decay laboratory data using pseudo-pressure and pseudo-time transformations

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