Numerical model for NAPL migration in double-porosity subsurface systems

The double-porosity concept has been successfully applied by many researchers to simulate fluid flow in oil reservoirs over the past few decades. These oil reservoirs were typically considered to be made of fractured or fissured rock, hence the usance of the double-porosity concept. Nonetheless, dou...

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Main Authors: Ngien, Su Kong, Ken, Tan Lit
Format: Conference or Workshop Item
Published: 2015
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Online Access:http://eprints.utm.my/id/eprint/63540/
https://www.iahr.org/site/cms/contentCategoryView.asp?category=342
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Institution: Universiti Teknologi Malaysia
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spelling my.utm.635402017-08-21T08:22:38Z http://eprints.utm.my/id/eprint/63540/ Numerical model for NAPL migration in double-porosity subsurface systems Ngien, Su Kong Ken, Tan Lit TJ Mechanical engineering and machinery The double-porosity concept has been successfully applied by many researchers to simulate fluid flow in oil reservoirs over the past few decades. These oil reservoirs were typically considered to be made of fractured or fissured rock, hence the usance of the double-porosity concept. Nonetheless, double-porosity may also exist in soil either through soil aggregation, or through soil features such as wormholes, cracks and root holes. These attributes in soil that cause the occurrence of double-porosity are also known as secondary porosity features and are akin to the reservoir rock fractures or fissures. In the case of groundwater contamination, the occurrence of double-porosity in soil is highly influential since immiscible fluids have been found to flow preferentially through the secondary porosity features. Ergo, a numerical model for non-aqueous phase liquids (NAPL) migration in double-porosity groundwater systems was developed. This model was modified from the conventional double-porosity model applied in the petroleum industry. The difference is that while the standard double-porosity models usually simulate the fluid flows in both continua making up the doubleporosity medium, the double-porosity model presented here focuses the modelling on the secondary porosity features in the soil, therefore making it more pertinent in the context of groundwater contamination. In the modified model, the phase saturations and relative permeabilities are expressed as functions of the capillary pressures. The resultant nonlinear governing partial differential equations are solved using numerical methods. The problem is discretized spatially using the Galerkin’s weighted-residual finite element method whereas a fully implicit scheme is used for temporal discretization. Verification of the developed model has been done against similar works in the open literature and the preferential flow of NAPL through the secondary porosity features was validated. 2015 Conference or Workshop Item PeerReviewed Ngien, Su Kong and Ken, Tan Lit (2015) Numerical model for NAPL migration in double-porosity subsurface systems. In: 36th IAHR World Congress, The Hague, Netherlands, 2015, 28 June-3 July, 2015, Netherlands. https://www.iahr.org/site/cms/contentCategoryView.asp?category=342
institution Universiti Teknologi Malaysia
building UTM Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Teknologi Malaysia
content_source UTM Institutional Repository
url_provider http://eprints.utm.my/
topic TJ Mechanical engineering and machinery
spellingShingle TJ Mechanical engineering and machinery
Ngien, Su Kong
Ken, Tan Lit
Numerical model for NAPL migration in double-porosity subsurface systems
description The double-porosity concept has been successfully applied by many researchers to simulate fluid flow in oil reservoirs over the past few decades. These oil reservoirs were typically considered to be made of fractured or fissured rock, hence the usance of the double-porosity concept. Nonetheless, double-porosity may also exist in soil either through soil aggregation, or through soil features such as wormholes, cracks and root holes. These attributes in soil that cause the occurrence of double-porosity are also known as secondary porosity features and are akin to the reservoir rock fractures or fissures. In the case of groundwater contamination, the occurrence of double-porosity in soil is highly influential since immiscible fluids have been found to flow preferentially through the secondary porosity features. Ergo, a numerical model for non-aqueous phase liquids (NAPL) migration in double-porosity groundwater systems was developed. This model was modified from the conventional double-porosity model applied in the petroleum industry. The difference is that while the standard double-porosity models usually simulate the fluid flows in both continua making up the doubleporosity medium, the double-porosity model presented here focuses the modelling on the secondary porosity features in the soil, therefore making it more pertinent in the context of groundwater contamination. In the modified model, the phase saturations and relative permeabilities are expressed as functions of the capillary pressures. The resultant nonlinear governing partial differential equations are solved using numerical methods. The problem is discretized spatially using the Galerkin’s weighted-residual finite element method whereas a fully implicit scheme is used for temporal discretization. Verification of the developed model has been done against similar works in the open literature and the preferential flow of NAPL through the secondary porosity features was validated.
format Conference or Workshop Item
author Ngien, Su Kong
Ken, Tan Lit
author_facet Ngien, Su Kong
Ken, Tan Lit
author_sort Ngien, Su Kong
title Numerical model for NAPL migration in double-porosity subsurface systems
title_short Numerical model for NAPL migration in double-porosity subsurface systems
title_full Numerical model for NAPL migration in double-porosity subsurface systems
title_fullStr Numerical model for NAPL migration in double-porosity subsurface systems
title_full_unstemmed Numerical model for NAPL migration in double-porosity subsurface systems
title_sort numerical model for napl migration in double-porosity subsurface systems
publishDate 2015
url http://eprints.utm.my/id/eprint/63540/
https://www.iahr.org/site/cms/contentCategoryView.asp?category=342
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