Impact of displacement rate on waterflood oil recovery under mixed-wet conditions

Yukie Tanino, Blessing Akamairo, Magali Christensen, Stephen A Bowden

Research output: Chapter in Book/Report/Conference proceedingConference contribution

Abstract

Under uniformly water-wetting conditions, it is well established that waterflood oil recovery remains independent of flood rate while the flow is capillary-dominated and furthermore, that the rate dependence emerges when the microscopic capillary number exceeds O(10-5). In contrast, there is no equivalent framework for interpreting the flood rate-dependence of oil recovery under mixed-wet conditions representative of oil reservoirs. Indeed, not even the appropriate definition of capillary number under mixed-wet conditions is established. In this paper, we focus specifically on oil recovery from mixed-wet porous media at high initial oil saturation and its dependence on water injection rate. We present laboratory measurements of oil distribution and its evolution during secondary waterflood at 2.5, 5.0, and 500 ft day-1. Oil distribution was directly imaged at the pore scale using a high-speed camera coupled to an optical microscope in a bed of calcite grains packed into a microfluidic chip. These measurements are benchmarked against bulk measurements of remaining oil saturation in limestone cores.
Data to date suggest that remaining oil saturation, So, after the same volume of water injection, displays a dependence on injection rate qualitatively similar to the classic capillary desaturation curve for uniformly water-wet media, with the rate dependence emerging at a higher injection rate under mixed-wet conditions than under water-wet conditions. However, unlike in uniformly water-wet media, the long-time (residual) So does not display a dependence on the rate. These findings may have important implications not only for oil recovery, but for a wide range of engineering applications involving mixed-wet porous media, e.g., geological CO2 storage, remediation of nonaqueous phase liquid (NAPL)-contaminated soils and aquifers and irrigation.
Original languageEnglish
Title of host publicationProceedings of International Symposium of the Society of Core Analysts 2015
Pages1-10
Number of pages10
Publication statusUnpublished - 2015
EventInternational Symposium of the Society of Core Analysts: 2015 - St. John's Newfoundland and Labrador, Canada
Duration: 16 Aug 201521 Aug 2015

Conference

ConferenceInternational Symposium of the Society of Core Analysts
CountryCanada
CitySt. John's Newfoundland and Labrador
Period16/08/1521/08/15

Fingerprint

oil
saturation
water
porous medium
rate
nonaqueous phase liquid
wetting
remediation
calcite
limestone
irrigation
aquifer
engineering
distribution

Cite this

Tanino, Y., Akamairo, B., Christensen, M., & Bowden, S. A. (2015). Impact of displacement rate on waterflood oil recovery under mixed-wet conditions. Unpublished. In Proceedings of International Symposium of the Society of Core Analysts 2015 (pp. 1-10)

Impact of displacement rate on waterflood oil recovery under mixed-wet conditions. / Tanino, Yukie; Akamairo, Blessing; Christensen, Magali; Bowden, Stephen A.

Proceedings of International Symposium of the Society of Core Analysts 2015. 2015. p. 1-10.

Research output: Chapter in Book/Report/Conference proceedingConference contribution

Tanino, Y, Akamairo, B, Christensen, M & Bowden, SA 2015, Impact of displacement rate on waterflood oil recovery under mixed-wet conditions. in Proceedings of International Symposium of the Society of Core Analysts 2015. pp. 1-10, International Symposium of the Society of Core Analysts, St. John's Newfoundland and Labrador, Canada, 16/08/15.
Tanino Y, Akamairo B, Christensen M, Bowden SA. Impact of displacement rate on waterflood oil recovery under mixed-wet conditions. In Proceedings of International Symposium of the Society of Core Analysts 2015. 2015. p. 1-10
Tanino, Yukie ; Akamairo, Blessing ; Christensen, Magali ; Bowden, Stephen A. / Impact of displacement rate on waterflood oil recovery under mixed-wet conditions. Proceedings of International Symposium of the Society of Core Analysts 2015. 2015. pp. 1-10
@inproceedings{250015602575454ba8f0544ef04a5d87,
title = "Impact of displacement rate on waterflood oil recovery under mixed-wet conditions",
abstract = "Under uniformly water-wetting conditions, it is well established that waterflood oil recovery remains independent of flood rate while the flow is capillary-dominated and furthermore, that the rate dependence emerges when the microscopic capillary number exceeds O(10-5). In contrast, there is no equivalent framework for interpreting the flood rate-dependence of oil recovery under mixed-wet conditions representative of oil reservoirs. Indeed, not even the appropriate definition of capillary number under mixed-wet conditions is established. In this paper, we focus specifically on oil recovery from mixed-wet porous media at high initial oil saturation and its dependence on water injection rate. We present laboratory measurements of oil distribution and its evolution during secondary waterflood at 2.5, 5.0, and 500 ft day-1. Oil distribution was directly imaged at the pore scale using a high-speed camera coupled to an optical microscope in a bed of calcite grains packed into a microfluidic chip. These measurements are benchmarked against bulk measurements of remaining oil saturation in limestone cores.Data to date suggest that remaining oil saturation, So, after the same volume of water injection, displays a dependence on injection rate qualitatively similar to the classic capillary desaturation curve for uniformly water-wet media, with the rate dependence emerging at a higher injection rate under mixed-wet conditions than under water-wet conditions. However, unlike in uniformly water-wet media, the long-time (residual) So does not display a dependence on the rate. These findings may have important implications not only for oil recovery, but for a wide range of engineering applications involving mixed-wet porous media, e.g., geological CO2 storage, remediation of nonaqueous phase liquid (NAPL)-contaminated soils and aquifers and irrigation.",
author = "Yukie Tanino and Blessing Akamairo and Magali Christensen and Bowden, {Stephen A}",
note = "ACKNOWLEDGEMENTS This material is based on work supported by the University of Aberdeen Chevron Fund, a Society of Petrophysics and Well Log Analysts grant, and an Aberdeen Formation Evaluation Society scholarship. M.C. was supported by the University of Aberdeen College of Physical Sciences scholarship. The authors thank undergraduate student Matthew P. Wilkie for the measurements of density and viscosity of the synthetic brine and Colin Taylor for the mercury injection porosimetry measurements on Indiana limestone.",
year = "2015",
language = "English",
pages = "1--10",
booktitle = "Proceedings of International Symposium of the Society of Core Analysts 2015",

}

TY - GEN

T1 - Impact of displacement rate on waterflood oil recovery under mixed-wet conditions

AU - Tanino, Yukie

AU - Akamairo, Blessing

AU - Christensen, Magali

AU - Bowden, Stephen A

N1 - ACKNOWLEDGEMENTS This material is based on work supported by the University of Aberdeen Chevron Fund, a Society of Petrophysics and Well Log Analysts grant, and an Aberdeen Formation Evaluation Society scholarship. M.C. was supported by the University of Aberdeen College of Physical Sciences scholarship. The authors thank undergraduate student Matthew P. Wilkie for the measurements of density and viscosity of the synthetic brine and Colin Taylor for the mercury injection porosimetry measurements on Indiana limestone.

PY - 2015

Y1 - 2015

N2 - Under uniformly water-wetting conditions, it is well established that waterflood oil recovery remains independent of flood rate while the flow is capillary-dominated and furthermore, that the rate dependence emerges when the microscopic capillary number exceeds O(10-5). In contrast, there is no equivalent framework for interpreting the flood rate-dependence of oil recovery under mixed-wet conditions representative of oil reservoirs. Indeed, not even the appropriate definition of capillary number under mixed-wet conditions is established. In this paper, we focus specifically on oil recovery from mixed-wet porous media at high initial oil saturation and its dependence on water injection rate. We present laboratory measurements of oil distribution and its evolution during secondary waterflood at 2.5, 5.0, and 500 ft day-1. Oil distribution was directly imaged at the pore scale using a high-speed camera coupled to an optical microscope in a bed of calcite grains packed into a microfluidic chip. These measurements are benchmarked against bulk measurements of remaining oil saturation in limestone cores.Data to date suggest that remaining oil saturation, So, after the same volume of water injection, displays a dependence on injection rate qualitatively similar to the classic capillary desaturation curve for uniformly water-wet media, with the rate dependence emerging at a higher injection rate under mixed-wet conditions than under water-wet conditions. However, unlike in uniformly water-wet media, the long-time (residual) So does not display a dependence on the rate. These findings may have important implications not only for oil recovery, but for a wide range of engineering applications involving mixed-wet porous media, e.g., geological CO2 storage, remediation of nonaqueous phase liquid (NAPL)-contaminated soils and aquifers and irrigation.

AB - Under uniformly water-wetting conditions, it is well established that waterflood oil recovery remains independent of flood rate while the flow is capillary-dominated and furthermore, that the rate dependence emerges when the microscopic capillary number exceeds O(10-5). In contrast, there is no equivalent framework for interpreting the flood rate-dependence of oil recovery under mixed-wet conditions representative of oil reservoirs. Indeed, not even the appropriate definition of capillary number under mixed-wet conditions is established. In this paper, we focus specifically on oil recovery from mixed-wet porous media at high initial oil saturation and its dependence on water injection rate. We present laboratory measurements of oil distribution and its evolution during secondary waterflood at 2.5, 5.0, and 500 ft day-1. Oil distribution was directly imaged at the pore scale using a high-speed camera coupled to an optical microscope in a bed of calcite grains packed into a microfluidic chip. These measurements are benchmarked against bulk measurements of remaining oil saturation in limestone cores.Data to date suggest that remaining oil saturation, So, after the same volume of water injection, displays a dependence on injection rate qualitatively similar to the classic capillary desaturation curve for uniformly water-wet media, with the rate dependence emerging at a higher injection rate under mixed-wet conditions than under water-wet conditions. However, unlike in uniformly water-wet media, the long-time (residual) So does not display a dependence on the rate. These findings may have important implications not only for oil recovery, but for a wide range of engineering applications involving mixed-wet porous media, e.g., geological CO2 storage, remediation of nonaqueous phase liquid (NAPL)-contaminated soils and aquifers and irrigation.

M3 - Conference contribution

SP - 1

EP - 10

BT - Proceedings of International Symposium of the Society of Core Analysts 2015

ER -