Connected pathway relative permeability from pore-scale imaging of imbibition

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Connected pathway relative permeability from pore-scale imaging of imbibition. / Berg, Steffen Ten; Ruecker, Maja; Ott, Holger et al.
in: Advances in Water Resources, Jahrgang 90.2016, Nr. April, 11.02.2016, S. 24-35.

Publikationen: Beitrag in FachzeitschriftArtikelForschung(peer-reviewed)

Harvard

Berg, ST, Ruecker, M, Ott, H, Georgiadis, A, van der Linde, H, Enzmann, F, Kersten, M, Armstrong, RT, de With, S, Becker, J & Wiegmann, A 2016, 'Connected pathway relative permeability from pore-scale imaging of imbibition', Advances in Water Resources, Jg. 90.2016, Nr. April, S. 24-35. https://doi.org/10.1016/j.advwatres.2016.01.010

APA

Berg, S. T., Ruecker, M., Ott, H., Georgiadis, A., van der Linde, H., Enzmann, F., Kersten, M., Armstrong, R. T., de With, S., Becker, J., & Wiegmann, A. (2016). Connected pathway relative permeability from pore-scale imaging of imbibition. Advances in Water Resources, 90.2016(April), 24-35. https://doi.org/10.1016/j.advwatres.2016.01.010

Vancouver

Berg ST, Ruecker M, Ott H, Georgiadis A, van der Linde H, Enzmann F et al. Connected pathway relative permeability from pore-scale imaging of imbibition. Advances in Water Resources. 2016 Feb 11;90.2016(April):24-35. doi: 10.1016/j.advwatres.2016.01.010

Author

Berg, Steffen Ten ; Ruecker, Maja ; Ott, Holger et al. / Connected pathway relative permeability from pore-scale imaging of imbibition. in: Advances in Water Resources. 2016 ; Jahrgang 90.2016, Nr. April. S. 24-35.

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@article{3f0b1d6ffafd4786a593e098c671fda0,
title = "Connected pathway relative permeability from pore-scale imaging of imbibition",
abstract = "Pore-scale images obtained from a synchrotron-based X-ray computed micro-tomography (µCT) imbibition experiment in sandstone rock were used to conduct Navier–Stokes flow simulations on the connected pathways of water and oil phases. The resulting relative permeability was compared with steady-state Darcy-scale imbibition experiments on 5 cm large twin samples from the same outcrop sandstone material. While the relative permeability curves display a large degree of similarity, the endpoint saturations for the µCT data are 10% in saturation units higher than the experimental data. However, the two datasets match well when normalizing to the mobile saturation range. The agreement is particularly good at low water saturations, where the oil is predominantly connected. Apart from different saturation endpoints, in this particular experiment where connected pathway flow dominates, the discrepancies between pore-scale connected pathway flow simulations and Darcy-scale steady-state data are minor overall and have very little impact on fractional flow. The results also indicate that if the pore-scale fluid distributions are available and the amount of disconnected non-wetting phase is low, quasi-static flow simulations may be sufficient to compute relative permeability. When pore-scale fluid distributions are not available, fluid distributions can be obtained from a morphological approach, which approximates capillary-dominated displacement. The relative permeability obtained from the morphological approach compare well to drainage steady state whereas major discrepancies to the imbibition steady-state experimental data are observed. The morphological approach does not represent the imbibition process very well and experimental data for the spatial arrangement of the phases are required. Presumably for modeling imbibition relative permeability an approach is needed that captures moving liquid-liquid interfaces, which requires viscous and capillary forces simultaneously.",
author = "Berg, {Steffen Ten} and Maja Ruecker and Holger Ott and A. Georgiadis and {van der Linde}, H. and F. Enzmann and M. Kersten and Armstrong, {R. T.} and {de With}, S. and J{\"u}rgen Becker and A. Wiegmann",
year = "2016",
month = feb,
day = "11",
doi = "10.1016/j.advwatres.2016.01.010",
language = "English",
volume = "90.2016",
pages = "24--35",
journal = "Advances in Water Resources",
issn = "1872-9657",
publisher = "Elsevier Ltd",
number = "April",

}

RIS (suitable for import to EndNote) - Download

TY - JOUR

T1 - Connected pathway relative permeability from pore-scale imaging of imbibition

AU - Berg, Steffen Ten

AU - Ruecker, Maja

AU - Ott, Holger

AU - Georgiadis, A.

AU - van der Linde, H.

AU - Enzmann, F.

AU - Kersten, M.

AU - Armstrong, R. T.

AU - de With, S.

AU - Becker, Jürgen

AU - Wiegmann, A.

PY - 2016/2/11

Y1 - 2016/2/11

N2 - Pore-scale images obtained from a synchrotron-based X-ray computed micro-tomography (µCT) imbibition experiment in sandstone rock were used to conduct Navier–Stokes flow simulations on the connected pathways of water and oil phases. The resulting relative permeability was compared with steady-state Darcy-scale imbibition experiments on 5 cm large twin samples from the same outcrop sandstone material. While the relative permeability curves display a large degree of similarity, the endpoint saturations for the µCT data are 10% in saturation units higher than the experimental data. However, the two datasets match well when normalizing to the mobile saturation range. The agreement is particularly good at low water saturations, where the oil is predominantly connected. Apart from different saturation endpoints, in this particular experiment where connected pathway flow dominates, the discrepancies between pore-scale connected pathway flow simulations and Darcy-scale steady-state data are minor overall and have very little impact on fractional flow. The results also indicate that if the pore-scale fluid distributions are available and the amount of disconnected non-wetting phase is low, quasi-static flow simulations may be sufficient to compute relative permeability. When pore-scale fluid distributions are not available, fluid distributions can be obtained from a morphological approach, which approximates capillary-dominated displacement. The relative permeability obtained from the morphological approach compare well to drainage steady state whereas major discrepancies to the imbibition steady-state experimental data are observed. The morphological approach does not represent the imbibition process very well and experimental data for the spatial arrangement of the phases are required. Presumably for modeling imbibition relative permeability an approach is needed that captures moving liquid-liquid interfaces, which requires viscous and capillary forces simultaneously.

AB - Pore-scale images obtained from a synchrotron-based X-ray computed micro-tomography (µCT) imbibition experiment in sandstone rock were used to conduct Navier–Stokes flow simulations on the connected pathways of water and oil phases. The resulting relative permeability was compared with steady-state Darcy-scale imbibition experiments on 5 cm large twin samples from the same outcrop sandstone material. While the relative permeability curves display a large degree of similarity, the endpoint saturations for the µCT data are 10% in saturation units higher than the experimental data. However, the two datasets match well when normalizing to the mobile saturation range. The agreement is particularly good at low water saturations, where the oil is predominantly connected. Apart from different saturation endpoints, in this particular experiment where connected pathway flow dominates, the discrepancies between pore-scale connected pathway flow simulations and Darcy-scale steady-state data are minor overall and have very little impact on fractional flow. The results also indicate that if the pore-scale fluid distributions are available and the amount of disconnected non-wetting phase is low, quasi-static flow simulations may be sufficient to compute relative permeability. When pore-scale fluid distributions are not available, fluid distributions can be obtained from a morphological approach, which approximates capillary-dominated displacement. The relative permeability obtained from the morphological approach compare well to drainage steady state whereas major discrepancies to the imbibition steady-state experimental data are observed. The morphological approach does not represent the imbibition process very well and experimental data for the spatial arrangement of the phases are required. Presumably for modeling imbibition relative permeability an approach is needed that captures moving liquid-liquid interfaces, which requires viscous and capillary forces simultaneously.

U2 - 10.1016/j.advwatres.2016.01.010

DO - 10.1016/j.advwatres.2016.01.010

M3 - Article

VL - 90.2016

SP - 24

EP - 35

JO - Advances in Water Resources

JF - Advances in Water Resources

SN - 1872-9657

IS - April

ER -