Using Well Windows in Full Field Reservoir Simulation

Mlacnik, M.J.; Heinemann, Z.E.

doi:10.2118/66371-ms

Cited by 15 publications

(15 citation statements)

References 12 publications

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“…In the context of LTS, such DDM algorithms were first analysed by Ewing and Lazarov [5] for parabolic problems in terms of stability, error estimates and convergence of the domain decomposition method. Then, Mlacnik and Heinemann [9,10] have proposed an extension to multiphase Darcy flow reservoir models using a sequential (non iterative) approach. They first compute, on the global LGR grid and with the coarse time step, an approximate solution using a simplified model.…”

Section: Introductionmentioning

confidence: 99%

Nearwell local space and time refinement in reservoir simulation

Kheriji

Masson

Moncorgé

2015

Mathematics and Computers in Simulation

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Abstract. In reservoir simulations, nearwell regions usually require finer space and time scales compared with the remaining of the reservoir domain. We present a domain decomposition algorithm for a two phase Darcy flow model coupling nearwell regions locally refined in space and time with a coarser reservoir discretization. The algorithm is based on an optimized Schwarz method using a full overlap at the coarse level. The main advantage of this approach is to apply to fully implicit discretizations of general multiphase flow models and to allow a simple optimization of the interface conditions based on a single phase flow equation.

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Section: Introductionmentioning

confidence: 99%

Nearwell local space and time refinement in reservoir simulation

Kheriji

Masson

Moncorgé

2015

Mathematics and Computers in Simulation

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“…One major concern dealing with near wellbore modeling is how to incorporate the proper grid around the near well region to simulate the pressure transient behaviour. Previous literature has discussed numerical well testing and the linking to the full field reservoir model (Settari, 1990;Puchyr, 1991;He et al, 1999;Mlacnik and Heinemann, 2003;Kamal et al, 2005;Al-Thawad et al, 2007). An integrated workflow is developed in this study for the field-based corner point grid geometry for matching well testing build up data.…”

Section: ) Numerical Well Testing and Hydraulic Fracturing Modelingmentioning

confidence: 99%

An Integrated Workflow for Reservoir Modeling and Flow Simulation of the Nikanassin Tight Gas Reservoir in the Western Canada Sedimentary Basin

Deng

Aguilera

Settari

2011

SPE Annual Technical Conference and Exhibition

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This paper presents an innovative workflow for characterization and reservoir simulation of the tight gas Nikanassin Group in the Western Canada Sedimentary Basin. Petrographic studies of the Nikanassin Group show the presence of (1) intergranular, (2) microfracture + slot, and (3) isolated (non effective) porosities. These porosities are handled with a mathematical triple porosity model for improved petrophysical analysis of the Nikanassin Group. Determination of pore throat apertures (r p35 ) facilitates facies mapping for reservoir simulation purposes. Numerical well testing of hydraulically fractured wells provides a way of tuning the static model with dynamic well testing information. In the case of open uncemented fractures and slots, numerical well testing indicates that the reduction of in-situ permeability can be more than two orders of magnitude. On the other hand in the case of partially cemented fractures and slots the reduction in permeability might be negligible. The approach permits an efficient representation of hydraulic fractures using transmissibility multipliers for the full field simulation of commingled tight reservoirs with multi-wells and multi-stage fractures.The result is a sound full field simulation model that permits a reasonable match of production and pressure histories, and forecasting of gas recovery under different well-spacing and depletion scenarios. As most Nikanassin tight gas wells are completed commingled, this research develops a procedure for production allocation of individual contributing formations.The study shows that there is a very large gas potential in the Nikanassin Group, particularly in the Lower Monteith Formation that can be exploited by reducing significantly the well spacing. The finding is significant as the tight gas Nikanassin Group extends for more than 15,000 km2 within Alberta and British Columbia, which suggests the potential for drilling thousands of wells in the region.

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“…Previous literature has discussed numerical well testing and the linking to the full field reservoir model (Settari 1990;Puchyr, 1991;He et al 1999;Mlacnik and Heinemann, 2003;Kamal et al 2005;Al-Thawad et al 2007). An integrated workflow developed in this paper on the field based corner point grid model is based on matching the well test build up data:…”

Section: Numerical Well Testingmentioning

confidence: 99%

Reservoir Characterization and Flow Simulation of a Low-Permeability Gas Reservoir: An Integrated Approach for Modeling Tommy Lakes Gas Field

Deng

Alfarhan²,

White³

et al. 2010

All Days

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The Tommy Lakes field is located in northeastern British Columbia, Canada; and is one of the largest Middle Triassic gas pools within the Western Canada Sedimentary Basin (WCSB). The major gas production formation (Halfway/Doig reservoirs) at Tommy Lakes field corresponds to shoreface sands with permeabilities ranging between 0.1 and 3 md, and porosities of 3 to12%. For the purpose of production optimization and field development, a full field reservoir model was developed with the integration of advanced reservoir characterization, hydraulic fracture modeling, and history matching techniques.This study presents an integrated workflow for modeling the low permeability Doig gas reservoir. A stochastic geostatistical reservoir model was developed based on concepts emanating from an outcrop analog analyzed with terrestrial LiDAR technology and 60 wells that represent the fundamental rock characteristics, structure, facies proportions and petrophysical properties of the Doig Anomalously Thick Sandstone Bodies (ATSB). Structural tops were interpreted from well logs and permeability/porosity relationships established from quantitative log analysis and core-log calibration. Facies were identified in cored intervals and were further grouped into 4 lithofacies. An artificial neural network was used for training the logs of key wells (GR, NPHI, RHOB) and populating the facies distribution of uncored wells. Facies-based log-derived porosity, permeability, shale volume and water saturation were assigned to grid blocks using sequential Gaussian simulation (SGS). Finally, the Monte-Carlo simulation approach was used to rank the key variables affecting OGIP in the uncertainty and optimization process.Flow based techniques were used for up-scaling reservoir properties into the coarse simulation grid. The full field simulation model was calibrated with buildup data and hydraulic fracture modeling of single wells. Production of the Doig channel from comingled wells was allocated systematically in order to achieve a good match of the gas production history and bottomhole pressures. Sensitivity analysis of fracture half length and its impact on ultimate gas recovery was investigated. This concludes with an integrated development strategy.It is concluded that integration of multiple domains leads to a valid full field reservoir model which is critical in developing an integrated strategy, predicting reservoir performance and optimizing gas production.

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Using Well Windows in Full Field Reservoir Simulation

Cited by 15 publications

References 12 publications

Nearwell local space and time refinement in reservoir simulation

Nearwell local space and time refinement in reservoir simulation

An Integrated Workflow for Reservoir Modeling and Flow Simulation of the Nikanassin Tight Gas Reservoir in the Western Canada Sedimentary Basin

Reservoir Characterization and Flow Simulation of a Low-Permeability Gas Reservoir: An Integrated Approach for Modeling Tommy Lakes Gas Field

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