Realistic History Matching of Cyclic Steam Stimulation Performance of Several Groups of Multilateral Wells in the Peace River Field, Canada

Mohiddin, Junaid Ghulam; Koci, Paul

doi:10.2118/107201-ms

Cited by 12 publications

(4 citation statements)

References 6 publications

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“…Moreover, one interesting result from this study is that the case without a predefined fracture layer yielded results that were more similar to the behavior observed in the field. This implies that earlier approaches, as performed by Lebel and Moriyama (1997), Koci and Mohiddin (2007), and Walters et al (2000) to model CSS with the use of predefined fracture layers, should not be used.…”

Section: Discussionmentioning

confidence: 99%

“…In another study conducted by Koci and Mohiddin (2007) for Shell's Peace River property, the authors outline two different methods in a widely applied simulator that can be used to include geomechanical effects in the model. The first is a reservoir-dilation and -recompaction model, also known as the Beattie-Boberg model (Beattie et al 1991).…”

Section: Previous Work On Numerical Simulation Of Steam Fracturingmentioning

confidence: 99%

“…Because the location, depth, and orientation of these hydraulic fractures are diffi-cult to determine, it is difficult to specify the location of these fractures. In the study conducted by Koci and Mohiddin (2007), a horizontal fracture was placed at the top of the reservoir and a pressure-dependent transmissibility modifier was applied to the top reservoir layer. These fractures will then open or close, depending on the reservoir pressure.…”

Section: Previous Work On Numerical Simulation Of Steam Fracturingmentioning

confidence: 99%

“…The estuarine zone has poorer quality (i.e., lower permeability) than the deltaic one. In current operations, closely spaced multilateral J-wells are drilled from a central pad facility (Koci and Mohiddin 2007). Shell is now shifting toward an inverted seven-spot pattern in which each pattern will cover 3.4 ha within the Bluesky formation (Shell Recovery Process 2009).…”

Section: Introductionmentioning

confidence: 99%

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Reservoir Simulation of Steam Fracturing in Early-Cycle Cyclic Steam Stimulation

Cokar

Gates

Kallos

2012

SPE Reservoir Evaluation &Amp; Engineering

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In cyclic steam stimulation (CSS), steam is injected above the fracture pressure into the oil-sands reservoir. In early cycles, the injected steam fractures the reservoir, creating a relatively thin dilated zone that allows rapid distribution of heat within the reservoir without excessive displacement of oil from the neighborhood of the wellbore. Numerical reservoir-simulation models of CSS that deal with the fracturing process have difficulty simultaneously capturing flowing bottomhole-pressure (BHP) behavior and steam injection rate. In this research, coupled reservoir-simulation (flow and heat transfer) and geomechanics models are investigated to model dynamic fracturing during the first cycle of CSS in an oil-sands reservoir. In Alberta, Canada, in terms of volumetric production rate, CSS is the largest thermal recovery technology for bitumen production, with production rates equal to approximately 1.3 million B/D in 2008. The average recovery factor from CSS is between 25 and 28% at the economic end of the process. This implies that the majority of bitumen remains in the ground. Because the mobility of the bitumen depends strongly on temperature, the performance of CSS is intimately linked to steam conformance in the reservoir, which is largely established during steam fracturing of the reservoir in the early cycles of the process. Thus, a fundamental understanding of the flow and geomechanical aspects of early-cycle CSS is critical. A detailed thermal reservoir-simulation model, including dilation and dynamic fracturing, was developed, with the use of a commercially available thermal reservoir simulator, to understand their effects on BHP and injection rate. The results demonstrate that geomechanics must be included to accurately model CSS. The results also suggest that the reservoir dilates during steam injection as the result of increases in reservoir temperature, which lead to thermal dilation and higher pore pressure.

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Section: Discussionmentioning

confidence: 99%

Section: Previous Work On Numerical Simulation Of Steam Fracturingmentioning

confidence: 99%

Section: Previous Work On Numerical Simulation Of Steam Fracturingmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Reservoir Simulation of Steam Fracturing in Early-Cycle Cyclic Steam Stimulation

Cokar

Gates

Kallos

2012

SPE Reservoir Evaluation &Amp; Engineering

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Peace River Carmon Creek Project—Optimization of Cyclic Steam Stimulation Through Experimental Design

Mohiddin

Koci

2007

SPE Annual Technical Conference and Exhibition

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Peace River Carmon Creek is a 100% Shell owned ultra-heavy oil lease located in north-western Alberta, Canada, approximately 700 km northwest of Edmonton (Fig. 1). It holds nearly eight billion barrels of 7°API oil in place, spread over 370 km2. The Carmon Creek Project targets possibly about half of that oil for development by cyclic steam stimulation (CSS). There are growth plans for a significant increase in oil production over the next five years. The purpose of this study was to optimize CSS well configuration and steaming strategy for each distinct reservoir area by deploying previously improved and history matched simulation models1. A full field static model was built, comprising over 400 wells. More detailed static sector models were also built for each distinct geological area and translated into elements of symmetry thermal simulation models. The choice of design parameters and handling of uncertainties were addressed in a phased manner. First, the smallest possible element of symmetry simulation model and the most efficient discrete fracture realization were determined. The next phase involved optimization of the well configuration and steaming strategy for each field area (based on approximate Net Present Value, NPV). The final phase entailed uncertainty analysis for the optimized design concepts and determining P15, P50, and P85 forecasts for each area. Experimental Design and Monte Carlo simulations were applied to further reduce the runs required for each phase. Although different optimum CSS designs were determined for each geological area, the modeling results can be generalized as follows:Horizontal well near the base of the reservoir is the optimum well type for CSS at Peace River.Well spacing less than 75 meters appears more attractive in the higher reservoir quality areas compared to the current assumption of 150 meters. In summary, a series of predictive CSS simulation models, primarily for horizontal wells, have been developed. Heavily aided by experimental design, a unique phased modeling workflow was applied to optimize well design and steaming strategy. Some of the suggested design components are already being tested at Peace River. Introduction Historically, various thermal recovery schemes have been piloted at Peace River, including in-situ combustion, steam drive, steam foam, steam assisted gravity drainage (SAGD) and CSS. At present, CSS with injection above fracture pressure is employed to extract the oil, most recently using closely spaced multi-lateral horizontal wells drilled from a central surface pad. The CSS target is the Bluesky formation, an approximately 30 m thick semi-consolidated sand layer buried at a depth of about 600 m, characterized by a wide range of reservoir properties such as oil viscosity, vertical to horizontal permeability ratio and reservoir thickness. These varying reservoir features are expected to result in different optimum CSS well configurations and steaming strategies for each geologically unique portion of the field. The purpose of this study was to determine these optimums.

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Modelling Subsurface Uncertainties with Experimental Design: Some Arguments of Non-Conformists

Lawal¹

2009

All Days

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As a consequence of limited capability for the acquisition, analysis and interpretation of subsurface data, uncertainties pervade the Exploration and Production (E&P) business. To minimise investment risks, robust development plans, premised on adequate understanding of uncertainties, are critical. Experimental Design (ED), complemented with Response Surface Method (RSM), which uses a statistical proxy equation to model the response (dependent variable) as a function of independent variables (uncertainties), is a common method for studying subsurface uncertainties. In this paper, current applications of ED to subsurface modelling are evaluated from fundamental principles- mathematical and physical consistencies of the proxy equations, as well as robustness in modelling uncertainties. Within the context of modelling and mitigating subsurface uncertainties, major shortcomings of the ED and their implications for decision-making are highlighted. These include inconsistency and non-uniqueness of proxy models, violation of basic theoretical physics, non-preservation of the correlation between variables that are known to be inherently related, non-controllability of input variables, under-estimation of the impact of uncertainties, and the challenge of constructing (interpolating) realistic simulation models from an ED output. Although ED is consistent with statistical principles, its description of reservoir physics is not satisfactory. In its present form, reservoir complexities are apparently too overwhelming for reliable modelling or optimisation by the proxy models. Consequently, it is recommended that the application of ED be limited to situations where a simple understanding of the effect of a controllable variable on a dependent variable is required, or where the range of uncertainties is well known within a narrow interval. These include production/injection management, ‘model-based’ control algorithms for ‘intelligent’ completions, business planning and similar areas of the E&P business characterised by continuous data, and where the independent variables could be engineered for the desired objectives.

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Realistic History Matching of Cyclic Steam Stimulation Performance of Several Groups of Multilateral Wells in the Peace River Field, Canada

Cited by 12 publications

References 6 publications

Reservoir Simulation of Steam Fracturing in Early-Cycle Cyclic Steam Stimulation

Reservoir Simulation of Steam Fracturing in Early-Cycle Cyclic Steam Stimulation

Peace River Carmon Creek Project—Optimization of Cyclic Steam Stimulation Through Experimental Design

Modelling Subsurface Uncertainties with Experimental Design: Some Arguments of Non-Conformists

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