Hierarchical approach for simulating fluid flow in normal fault zones

Berg, Silje S.; Øian, Erlend

doi:10.1144/1354-079305-676

Cited by 19 publications

(17 citation statements)

References 52 publications

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“…Syversveen et al 2006) or two-phase fault rock properties (e.g. Berg & Øian 2007). Although different groups of workers may apply different geological idealizations of faults to define either the content and structure of the locally refined grids or the input to an upscaling solution, the overriding aim is identical: to represent more accurately the flow implications of fault-related geological heterogeneity.…”

Section: Discussionmentioning

confidence: 99%

“…Ringrose et al 1993;Manzocchi et al 1998Manzocchi et al , 2002Rivenaes & Dart 2002;Al-Busafi et al 2005;Berg & Øian 2007). The example reservoirs used in this study -although synthetic -contain scales, rates, fluids and pressures representative of real reservoirs (Manzocchi et al 2008a, Matthews et al 2008 and are, therefore, a good test of whether two-phase fault rock properties may, indeed, be of practical significance.…”

Section: Fault Rock Effectsmentioning

confidence: 99%

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Faults in conventional flow simulation models: a consideration of representational assumptions and geological uncertainties

Manzocchi

Heath

Palananthakumar

et al. 2008

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Even when geologically based methods are used to determine fault rock permeabilities and thicknesses for input into flow simulators, a wide range of simplifying assumptions regarding fault structure and content are still present. Many of these assumptions are addressed by defining quantitative and flexible methods for realistic parameterization of fault-related uncertainties, and by defining automated methods for including these effects routinely in full-field flow simulation modelling. The fault effects considered include: the two-phase properties of fault rocks; the spatial distributions of naturally variable or uncertain single-phase fault rock properties and fault throws; and the frequencies and properties of sub-resolution fault system or fault zone complexities, including sub-seismic faults, normal drag and damage zones, paired slip surfaces and fault relay zones. Innovative two-phase or geometrical upscaling approaches implemented in a reservoir simulator preprocessor provide transmissibility solutions incorporating the effect, but represented within the geometrical framework of the full-field flow simulation model. The solutions and flexible workflows are applied and discussed within the context of a sensitivity study carried out on two faulted versions of the same full-field flow simulation model. Significant influence of some of these generally neglected fault-related assumptions and uncertainties is revealed.

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Section: Discussionmentioning

confidence: 99%

Section: Fault Rock Effectsmentioning

confidence: 99%

Faults in conventional flow simulation models: a consideration of representational assumptions and geological uncertainties

Manzocchi

Heath

Palananthakumar

et al. 2008

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“…Clearly fault zones with many tens or even hundreds of such deformation bands will have significantly reduced bulk permeability. Upscaling such multiple, millimetre-scale, and perhaps laterally impersistent, features into an equivalent cell permeability for numerical simulation purposes is highly problematical (e.g Walsh et al 1998;Berg & Øian 2007), and beyond the scope of this current paper. Away from the free CO 2 plume, we are mainly interested in single-phase (water) flow through much of the reservoir, so it may be that more empirical information from regional hydrogeological studies (e.g.…”

Section: Discussionmentioning

confidence: 99%

“…The flow of multi-phase fluids through flow barriers is a subject of considerable current research in the oil industry (e.g. Berg & Øian 2007). In the context of this paper however, we are principally interested in single-phase flow through faults to assess how easily formation water can be displaced laterally through a reservoir as CO 2 is introduced.…”

Section: Reservoir With Flow Barriersmentioning

confidence: 99%

Flow processes and pressure evolution in aquifers during the injection of supercritical CO ₂ as a greenhouse gas mitigation measure

Chadwick

Noy

Holloway

2009

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ABSTRACT:Regional saline aquifers offer the greatest potential for very large-scale underground CO 2 storage as a means of mitigating greenhouse gas emissions. Their dynamic storage capacity, in terms of induced increases in formation pressure, will limit the rate at which CO 2 can be injected and may ultimately limit the amount of CO 2 that can be stored. Generic flow models have been generated to examine the effects on pressure evolution of various reservoir parameters (dimensions, permeability, porosity, presence and nature of flow barriers). CO 2 injection involves dominantly hydrogeological (single-phase flow) processes in much of the reservoir and surrounding adjacent strata, with additional two-phase flow effects around the CO 2 plume itself. Large, thick aquifers with no significant flow barriers can accept high injection rates (~10 million tonnes of CO 2 per year) without undue pressure effects. However, flow barriers, such as faults, increase induced pressures considerably; for reservoirs with such features, careful site characterisation and operational planning will be required for large storage projects. The principles established from the generic modelling were then applied to a real aquifer storage operation at Sleipner in the North Sea. Here CO 2 is being injected into the Utsira Sand, a large relatively homogeneous reservoir. Modelling indicates that pressure increase should be negligible. In fact observed wellhead pressures do show a small rise, but this can be attributed to temperature changes in the fluid column in the wellbore. Pressure changes in the reservoir are likely to be very small.

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“…The fact that we are assuming the fault to be a single plane, compared to the complex fault zone modelled by Berg and Øian (2007) means that we did not need to perform such an investigation for the present study.…”

Section: Article In Pressmentioning

confidence: 99%

Laboratory measurements of the relative permeability of cataclastic fault rocks: An important consideration for production simulation modelling

Al-Hinai

Fisher

Al-Busafi³

et al. 2008

Marine and Petroleum Geology

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Hierarchical approach for simulating fluid flow in normal fault zones

Cited by 19 publications

References 52 publications

Faults in conventional flow simulation models: a consideration of representational assumptions and geological uncertainties

Faults in conventional flow simulation models: a consideration of representational assumptions and geological uncertainties

Flow processes and pressure evolution in aquifers during the injection of supercritical CO ₂ as a greenhouse gas mitigation measure

Laboratory measurements of the relative permeability of cataclastic fault rocks: An important consideration for production simulation modelling

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Hierarchical approach for simulating fluid flow in normal fault zones

Cited by 19 publications

References 52 publications

Faults in conventional flow simulation models: a consideration of representational assumptions and geological uncertainties

Faults in conventional flow simulation models: a consideration of representational assumptions and geological uncertainties

Flow processes and pressure evolution in aquifers during the injection of supercritical CO 2 as a greenhouse gas mitigation measure

Laboratory measurements of the relative permeability of cataclastic fault rocks: An important consideration for production simulation modelling

Contact Info

Product

Resources

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Flow processes and pressure evolution in aquifers during the injection of supercritical CO ₂ as a greenhouse gas mitigation measure