Numerical investigation on the effect of boundary conditions on the scaling of spontaneous imbibition

We present a numerical validation of the scaling group presented by Schmid and Geiger ((2012) Water Resour. Res. 48, 3) for Spontaneous Imbibition (SI) through simulating a core sample bounded by the wetting fluid. We combine the results of the simulations with the semi-analytical model for counter-...

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Main Authors: Abd Abdul Salam, Alyafei Nayef
Format: Article
Language:English
Published: EDP Sciences 2018-01-01
Series:Oil & Gas Science and Technology
Online Access:https://doi.org/10.2516/ogst/2018060
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spelling doaj-9c7294bbf0ae4046bdca55784c8002a52021-02-02T08:21:17ZengEDP SciencesOil & Gas Science and Technology1294-44751953-81892018-01-01737110.2516/ogst/2018060ogst180052Numerical investigation on the effect of boundary conditions on the scaling of spontaneous imbibitionAbd Abdul SalamAlyafei NayefWe present a numerical validation of the scaling group presented by Schmid and Geiger ((2012) Water Resour. Res. 48, 3) for Spontaneous Imbibition (SI) through simulating a core sample bounded by the wetting fluid. We combine the results of the simulations with the semi-analytical model for counter-current spontaneous imbibition presented by Schmid et al. ((2011) Water Resour. Res. 47, 2) to validate the upscaling of laboratory experiments to field dimensions using dimensionless time. We then present a detailed parametric study on the effect of Boundary Conditions (BC) and characteristic length to compare imbibition assisted oil recovery with several types of boundary conditions. We demonstrate that oil recovery was the fastest and most efficient when all faces are open to flow. We also demonstrate that all cases scale with the non-dimensionless time suggested by Schmid and Geiger ((2012) Water Resour. Res. 48, 3) and show a close match to the numerical simulation and the semi-analytical solution. Moreover, we discuss how the effect of constructing a model with varying grid sizes and dimensions affects the accuracy of the results through comparing the results of the 2-D and 3-D models. We observe that the 3-D model proved superior in the accuracy of the results to simulate simple counter-current SI. However, we deduce that 2-D models yield satisfying enough results in a timely manner in the One End Open (OEO) and Two Ends Open (TEO) cases, compared to 3-D models which are time-consuming. We finally conclude that the non-dimensionless time of Schmid and Geiger ((2012) Water Resour. Res. 48, 3) works well with counter-current SI cases regardless of the boundary condition imposed on the core.https://doi.org/10.2516/ogst/2018060
collection DOAJ
language English
format Article
sources DOAJ
author Abd Abdul Salam
Alyafei Nayef
spellingShingle Abd Abdul Salam
Alyafei Nayef
Numerical investigation on the effect of boundary conditions on the scaling of spontaneous imbibition
Oil & Gas Science and Technology
author_facet Abd Abdul Salam
Alyafei Nayef
author_sort Abd Abdul Salam
title Numerical investigation on the effect of boundary conditions on the scaling of spontaneous imbibition
title_short Numerical investigation on the effect of boundary conditions on the scaling of spontaneous imbibition
title_full Numerical investigation on the effect of boundary conditions on the scaling of spontaneous imbibition
title_fullStr Numerical investigation on the effect of boundary conditions on the scaling of spontaneous imbibition
title_full_unstemmed Numerical investigation on the effect of boundary conditions on the scaling of spontaneous imbibition
title_sort numerical investigation on the effect of boundary conditions on the scaling of spontaneous imbibition
publisher EDP Sciences
series Oil & Gas Science and Technology
issn 1294-4475
1953-8189
publishDate 2018-01-01
description We present a numerical validation of the scaling group presented by Schmid and Geiger ((2012) Water Resour. Res. 48, 3) for Spontaneous Imbibition (SI) through simulating a core sample bounded by the wetting fluid. We combine the results of the simulations with the semi-analytical model for counter-current spontaneous imbibition presented by Schmid et al. ((2011) Water Resour. Res. 47, 2) to validate the upscaling of laboratory experiments to field dimensions using dimensionless time. We then present a detailed parametric study on the effect of Boundary Conditions (BC) and characteristic length to compare imbibition assisted oil recovery with several types of boundary conditions. We demonstrate that oil recovery was the fastest and most efficient when all faces are open to flow. We also demonstrate that all cases scale with the non-dimensionless time suggested by Schmid and Geiger ((2012) Water Resour. Res. 48, 3) and show a close match to the numerical simulation and the semi-analytical solution. Moreover, we discuss how the effect of constructing a model with varying grid sizes and dimensions affects the accuracy of the results through comparing the results of the 2-D and 3-D models. We observe that the 3-D model proved superior in the accuracy of the results to simulate simple counter-current SI. However, we deduce that 2-D models yield satisfying enough results in a timely manner in the One End Open (OEO) and Two Ends Open (TEO) cases, compared to 3-D models which are time-consuming. We finally conclude that the non-dimensionless time of Schmid and Geiger ((2012) Water Resour. Res. 48, 3) works well with counter-current SI cases regardless of the boundary condition imposed on the core.
url https://doi.org/10.2516/ogst/2018060
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