2015 eage mps poster nwb

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Introduction New applications are being developed in the field of reservoir modeling to answer questions about CO₂ storage and CO₂ enhanced oil recovery (EOR). The Energy & Environmental Research Center (EERC) and the Plains CO₂ Reduction Partnership Program, in collaboration with the U.S. Department of Energy, have been constructing 3-D geocellular models for the purposes of studying CO₂ storage and CO₂ EOR. These efforts are gaining importance as we continue to investigate methods in climate change mitigation and greenhouse gas reduction.  Targets for potential geologic storage of CO₂ may consist of a variety of reservoir types, comprising heterogeneous lithologies from numerous depositional environments. Each depositional environment contains its own reservoir and nonreservoir rock based on 1) the presence of economically viable petrophysical properties (porosity and permeability); 2) the existence of temperature and pressure conditions effective in keeping injected CO₂ in the supercritical phase; and 3) the presence of a competent cap rock or seal to limit vertical mobility of sequestered CO₂. An understanding of reservoir hydrodynamics (where injected fluids may migrate or accumulate) is necessary to accurately model and monitor CO₂ injection. An additional consideration for realistic scenarios is the proximity to CO₂ sources for economic viability of CO₂ storage. The characterization and assessment of geologic targets for potential CO₂ storage are achieved through the construction and simulation of a reservoir model. The geologic modeling workflow includes 1) data acquisition; 2) structural modeling; 3) data upscaling and property modeling utilizing advanced geostatistical methods; 4) uncertainty analysis and history-matching; and 5) predictive simulations of CO₂ injection, pressure response, fluid saturation, and migration.  Several geostatistical approaches are available to assist in reducing uncertainty with various data sets. If the depositional environment is well understood, an optimized facies model can be constructed by using a unique method called multiple-point statistics (MPS). Unlike variogram-based algorithms, MPS uses a training image to determine facies associations between control points in the 3-D grid (Strebelle and Journel, 2002; Caers and Zhang, 2004). MPS Facies Modeling: Training Images and Control Points Training Image: Idealized reservoir volume containing pattern information (facies, facies stacking, lateral facies associations, and facies proportions) in a format that can be measured by modeling software. Control Point: Hard data (known conditions at a particular location) which is used to guide an MPS distribution. The actual facies distribution process is well discussed by Caers and Zhang (2004) and is achieved by 1) specification of a seed value (starting point within the 3-D grid) and definition of a random path; 2) searching for the nearest control points or previously simulated cells; 3) construction of a probability model based upon proximal control points and the relationships measured from the training image; 4) assignment of the most probable value to the unknown cell; and 5) moving to the next unknown cell, following the predefined random path, to repeat the process until all cells have been visited. The ability to apply geologic understanding of a depositional model to estimate conditions in unsampled locations is a strength not available in variogram- based methods and may result in more realistic results (an example being the knowledge that fluvial facies are likely to exhibit high connectivity rather than a widely scattered distribution of fluvial facies). Variogram-based statistical methods are perhaps better suited for the distribution of petrophysical properties within each facies, needing only to apply a general understanding of anisotropic trends. It should be noted that even with a valid training image, the results will likely not be geologically sound without accurate control points to guide the distribution. Without using control points, the resulting facies distribution will be statistically viable in comparison with the training image, but it is unlikely that a realistic result will be achieved. The EERC has begun construction of an MPS training image “library” created to house and archive training images used to develop reservoir facies models for use in future investigations. The EERC has developed several reservoir models to further investigations of potential CO₂ storage and EOR using MPS methods, including small-/local-scale models (pinnacle reefs, multiple reef complexes, and carbonate mound accumulations 2–30 km in diameter), oil field-scale, and basin-scale clastic and carbonate models. The facies models constructed in these efforts have been used to constrain petrophysical property distributions (porosity, permeability) which are necessary for numerical simulations of fluid flow and pressure effects to better understand the fate of injected CO₂. MPS is a tool incorporated within high-performance reservoir modeling software capable of 3-D geocellular model construction, such as Schlumberger’s Petrel Software, and is proving effective in estimating reservoir facies in unsampled locations. The MPS method allows the user to incorporate a preexisting knowledge of the spatial relations and proportions of geologic constituents in the creation of a more realistic facies model. The variogram- based statistical methods do not allow the user to apply such knowledge of reservoir facies and may produce questionable results in some scenarios. Variogram-based statistical methods are better suited for the distribution of petrophysical properties within each facies, needing only to apply a general understanding of porosity and permeability anisotropic trends. Reservoir models constructed for the applications of CO₂ storage and EOR at the EERC have used MPS to capture realistic geologic heterogeneity. Geologic heterogeneity controls porosity and permeability distributions, which, in turn, control preferential fluid flow, pressure response and, ultimately, CO₂ storage efficiency and capacity. Caers, J., and Zhang, T., 2004, Multiple-point geostatistics—a quantitative vehicle for integrating geologic analogs into multiple reservoir models, in Integration of outcrop and modern analogs in reservoir modeling: AAPG Memoir 80, p. 383–394. Strebelle, S.B., and Journel, A.G., 2002, Reservoir modeling using multiple-point statistics: Society of Petroleum Engineers Annual Technical Conference and Exhibition, New Orleans, Louisiana, September 30 – October 3, 2001, SPE Paper 71324, 16 p. This material is based upon work performed under U.S. Department of Energy Cooperative Agreement No. DE-FC26-05NT42592. Multiscale Reservoir Modeling for CO 2 Storage and Enhanced Oil Recovery Using Multiple Point Statistics N.W. Bosshart, J.R. Braunberger, M.E. Burton-Kelly, N.W. Dotzenrod, and C.D. Gorecki Acknowledgments References Summary EERC Case Studies MPS Training Image Library Deeply Incised Fluvial Channel Adaptive Channel Incised Fluvial Channel with Oxbows High-Density Channel System Fluvio-Deltaic Facies Anastomosing Channel System Carbonate Shelf – Peritidal System Carbonate Mounds Carbonate with Karst Dissolution Structures Karst Dissolution Structures Local strucure: reef MPS facies model example (from left to right): geologic interpretation of facies associations, training image, full facies distribution, and facies cross sections to show internal structure. Field-scale: complex sandstone reservoir with different geobody regions, each having an individual training image and resulting facies distribution. Deltaic Channel Channel Infill with Longshore Drift Deposits Tidal Channel System Incised fluvial channel Deltaic Channel Levee Deposits Barrier Bar Front and Back Bar Deposits Facies Fluvio-Deltaic Clean Sand Delta Silty Sand Shale Porosity 0.28 0.20 0.10 0.00 Permeability 100.0000 10.0000 1.0000 0.1000 Basin-scale: fluvio-deltaic MPS facies realization used to constrain successive porosity and permeability models. ©2015 University of North Dakota Energy & Environmental Research Center 9/15 CO 2 from Pipeline CO 2 Injection CO 2 and Oil Separation of CO 2 and Oil Oil Tank CO 2 Compression Thousands of Feet Energy & Environmental Research Center • University of North Dakota • Grand Forks, North Dakota, USA Grid K-layer slice of variogram-based fluvial facies distribution with nine control points and an anisotropic ratio of 6:1 (major-to-minor ranges) leveraging a Local Varying Azimuth method Variogram-Based Fluvial Facies Fluvial and Levee Deposits Only Local Varying Azimuth Surface Variogram-Based Facies Distribution Multiple-Point Statistics Facies Distribution Grid K-layer slice of MPS facies distribution with nine control points and using the training image at the far left. MPS Fluvial Training Image MPS Test Fluvial Facies Training Image Fluvial and Levee Deposits Only MPS Test Fluvial and Levee Deposits Only LVA: Applying a contoured anisotropy surface (compass degrees) to guide anisotropy trends in a facies distribution. Local Varying Azimuth 140.00 100.00 60.00 20.00

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Page 1: 2015 EAGE MPS Poster NWB

Introduction New applications are being developed in the field of reservoir modeling to answer questions about CO₂ storage and CO₂ enhanced oil recovery (EOR). The Energy & Environmental Research Center (EERC) and the Plains CO₂ Reduction Partnership Program, in collaboration with the U.S. Department of Energy, have been constructing 3-D geocellular models for the purposes of studying CO₂ storage and CO₂ EOR. These efforts are gaining importance as we continue to investigate methods in climate change mitigation and greenhouse gas reduction.  Targets for potential geologic storage of CO₂ may consist of a variety of reservoir types, comprising heterogeneous lithologies from numerous depositional environments. Each depositional environment contains its own reservoir and nonreservoir rock based on 1) the presence of economically viable petrophysical properties (porosity and permeability); 2) the existence of temperature and pressure conditions effective in keeping injected CO₂ in the supercritical phase; and 3) the presence of a competent cap rock or seal to limit vertical mobility of sequestered CO₂. An understanding of reservoir hydrodynamics (where injected fluids may migrate or accumulate) is necessary to accurately model and monitor CO₂ injection. An additional consideration for realistic scenarios is the proximity to CO₂ sources for economic viability of CO₂ storage. The characterization and assessment of geologic targets for potential CO₂ storage are achieved through the construction and simulation of a reservoir model. The geologic modeling workflow includes 1) data acquisition; 2) structural modeling; 3) data upscaling and property modeling utilizing advanced geostatistical methods; 4) uncertainty analysis and history-matching; and 5) predictive simulations of CO₂ injection, pressure response, fluid saturation, and migration.  Several geostatistical approaches are available to assist in reducing uncertainty with various data sets. If the depositional environment is well understood, an optimized facies model can be constructed by using a unique method called multiple-point statistics (MPS). Unlike variogram-based algorithms, MPS uses a training image to determine facies associations between control points in the 3-D grid (Strebelle and Journel, 2002; Caers and Zhang, 2004).

MPS Facies Modeling: Training Images and Control PointsTraining Image: Idealized reservoir volume containing pattern information (facies, facies stacking, lateral facies associations, and facies proportions) in a format that can be measured by modeling software.

Control Point: Hard data (known conditions at a particular location) which is used to guide an MPS distribution.

The actual facies distribution process is well discussed by Caers and Zhang (2004) and is achieved by 1) specification of a seed value (starting point within the 3-D grid) and definition of a random path; 2) searching for the nearest control points or previously simulated cells; 3) construction of a probability model based upon proximal control points and the relationships measured from the training image; 4) assignment of the most probable value to the unknown cell; and 5) moving to the next unknown cell, following the predefined random path, to repeat the process until all cells have been visited.

The ability to apply geologic understanding of a depositional model to estimate conditions in unsampled locations is a strength not available in variogram-based methods and may result in more realistic results (an example being the knowledge that fluvial facies are likely to exhibit high connectivity rather than a widely scattered distribution of fluvial facies). Variogram-based statistical methods are perhaps better suited for the distribution of petrophysical properties within each facies, needing only to apply a general understanding of anisotropic trends.

It should be noted that even with a valid training image, the results will likely not be geologically sound without accurate control points to guide the distribution. Without using control points, the resulting facies distribution will be statistically viable in comparison with the training image, but it is unlikely that a realistic result will be achieved. The EERC has begun construction of an MPS training image “library” created to house and archive training images used to develop reservoir facies models for use in future investigations.

The EERC has developed several reservoir models to further investigations of potential CO₂ storage and EOR using MPS methods, including small-/local-scale models (pinnacle reefs, multiple reef complexes, and carbonate mound accumulations 2–30 km in diameter), oil field-scale, and basin-scale clastic and carbonate models. The facies models constructed in these efforts have been used to constrain petrophysical property distributions (porosity, permeability) which are necessary for numerical simulations of fluid flow and pressure effects to better understand the fate of injected CO₂.

MPS is a tool incorporated within high-performance reservoir modeling software capable of 3-D geocellular model construction, such as Schlumberger’s Petrel Software, and is proving effective in estimating reservoir facies in unsampled locations. The MPS method allows the user to incorporate a preexisting knowledge of the spatial relations and proportions of geologic constituents in the creation of a more realistic facies model. The variogram-based statistical methods do not allow the user to apply such knowledge of reservoir facies and may produce questionable results in some scenarios. Variogram-based statistical methods are better suited for the distribution of petrophysical properties within each facies, needing only to apply a general understanding of porosity and permeability anisotropic trends.

Reservoir models constructed for the applications of CO₂ storage and EOR at the EERC have used MPS to capture realistic geologic heterogeneity. Geologic heterogeneity controls porosity and permeability distributions, which, in turn, control preferential fluid flow, pressure response and, ultimately, CO₂ storage efficiency and capacity.

Caers, J., and Zhang, T., 2004, Multiple-point geostatistics—a quantitative vehicle for integrating geologic analogs into multiple reservoir models, in Integration of outcrop and modern analogs in reservoir modeling: AAPG Memoir 80, p. 383–394.

Strebelle, S.B., and Journel, A.G., 2002, Reservoir modeling using multiple-point statistics: Society of Petroleum Engineers Annual Technical Conference and Exhibition, New Orleans, Louisiana, September 30 – October 3, 2001, SPE Paper 71324, 16 p.

This material is based upon work performed under U.S. Department of EnergyCooperative Agreement No. DE-FC26-05NT42592.

Multiscale Reservoir Modeling for CO2 Storage and Enhanced Oil Recovery Using Multiple Point StatisticsN.W. Bosshart, J.R. Braunberger, M.E. Burton-Kelly, N.W. Dotzenrod, and C.D. Gorecki

Acknowledgments References

Summary

EERC Case Studies

MPS Training Image Library

Deeply Incised Fluvial Channel Adaptive Channel

Incised Fluvial Channel with Oxbows High-Density Channel System

Fluvio-Deltaic Facies Anastomosing Channel System

Carbonate Shelf – Peritidal System Carbonate Mounds

Carbonate with Karst Dissolution Structures

Karst Dissolution Structures

Local strucure: reef MPS facies model example (from left to right): geologic interpretation of facies associations, training image, full facies distribution, and facies cross sections to show internal structure.

Field-scale: complex sandstone reservoir with different geobody regions, each having an individual training image and resulting facies distribution.

Deltaic Channel

Channel Infill with Longshore Drift

Deposits

Tidal Channel System

Incised fluvial channel

Deltaic Channel Levee Deposits

Barrier Bar Front and Back Bar Deposits

Facies

Fluvio-DeltaicClean Sand

Delta Silty Sand

Shale

Porosity0.28

0.20

0.10

0.00

Permeability100.0000

10.0000

1.0000

0.1000

Basin-scale: fluvio-deltaic MPS facies realization used to constrain successive porosity and permeability models.

©2015 University of North Dakota Energy & Environmental Research Center 9/15

CO2 from Pipeline CO2 Injection

CO2 and Oil

Separation of CO2 and Oil Oil TankCO2 Compression

Tho

usan

ds o

f Feet

Energy & Environmental Research Center • University of North Dakota • Grand Forks, North Dakota, USA

Grid K-layer slice of variogram-based fluvial facies distribution with nine control points and an anisotropic ratio of 6:1 (major-to-minor ranges) leveraging a Local Varying Azimuth method

Variogram-Based Fluvial Facies

Fluvial and Levee Deposits OnlyLocal Varying Azimuth Surface

Variogram-Based Facies Distribution

Multiple-Point Statistics Facies Distribution

Grid K-layer slice of MPS facies distribution with nine control points and using the training image at the far left.

MPS Fluvial Training Image MPS Test Fluvial Facies

Training Image Fluvial and Levee Deposits Only

MPS Test Fluvial and Levee Deposits Only

LVA: Applying a contoured anisotropy surface (compass degrees) to guide anisotropy trends in a facies distribution.

Local Varying Azimuth

140.00

100.00

60.00

20.00