Miscibility Variation in Compositionally Grading Reservoirs

Høier, Lars; Whitson, Curtis Hays

doi:10.2118/69840-pa

Cited by 44 publications

(38 citation statements)

References 13 publications

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“…The details of the fluid description for Oil C are given by Høier. 15 Finally, the reservoir fluid D is a 12-component representation of the fluid reported by Zick, 16 with a saturation pressure of 102 atm at 358 K. (See Jessen 7 for the fluid description). A summary of the different displacement processes is given in Table 2.…”

Section: Multicomponent Systemsmentioning

confidence: 99%

Interplay of Phase Behavior and Numerical Dispersion in Finite-Difference Compositional Simulation

Jessen¹,

Stenby²,

Orr³

2004

SPE Journal

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Compositional simulation of multicontact miscible (or nearmiscible) gas injection problems is typically performed by use of numerical finite-difference (FD) schemes. Such simulations are intrinsically affected by numerical dispersion.* In this paper, we propose a method to assess the sensitivity of a particular displacement calculation to the effects of numerical dispersion for systems with realistic multicomponent fluid descriptions. We use two simple ternary systems to illustrate how dispersion and convection interact to determine displacement composition paths and to define a "dispersive distance." We show how the dispersive distance relates to displacement performance with a detailed analysis of grid size effects on the recovery predictions for 1D displacements of a CH 4 -C 4 -C 10 system by pure N 2 and mixtures of N 2 and CH 4 . We then show that the sensitivity of multicomponent compositional simulations also correlates well with the dispersive distance. We demonstrate that quantitative difference between oil recovery predicted by coarse-grid numerical simulations, and values obtained from analytical solutions to the conservation equations, can be estimated well from calculating the distance between the dilution line and the composition path predicted by the method of characteristics. Finally, we apply the assessment of sensitivity to 2D displacements in a heterogeneous porous medium to demonstrate the interplay of phase behavior, adverse mobility, heterogeneity, and numerical dispersion.

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Section: Multicomponent Systemsmentioning

confidence: 99%

Interplay of Phase Behavior and Numerical Dispersion in Finite-Difference Compositional Simulation

Jessen¹,

Stenby²,

Orr³

2004

SPE Journal

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“…Recoveries also may be affected by initial fluid distributions (e.g., variation in minimum miscibility pressure), as shown by Høier and Whitson. 40,41 Another important task is quantifying the uncertainty in the initial fluid distribution. Together with uncertainties in other reservoir parameters such as permeability, reservoir unit volumes, reservoir unit communication, and relative permeabilities, engineers are expected to generate cases that define limits of probable production forecasts-so-called P10, P50, and P90 cases.…”

Section: Fluid Initialization In Reservoir Modelsmentioning

confidence: 99%

Compositional Grading—Theory and Practice

Høier

Whitson²

2001

SPE Reservoir Evaluation &Amp; Engineering

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This paper quantifies the potential variation in composition and pressure/volume/temperature (PVT) properties with depth owing to gravity, chemical, and thermal forces. A wide range of reservoir fluid systems has been studied using all of the known published models for thermal diffusion in the nonisothermal mass-transport problem.Previous studies dealing with the combined effects of gravity and vertical thermal gradients on compositional grading have been either (1) of a theoretical nature, without examples from reservoir fluid systems, or (2) proposing one particular thermal-diffusion model, usually for a specific reservoir, without comparing the results with other thermal-diffusion models.We give a short review of gravity/nonisothermal models published to date. In particular, we show quantitative differences in the various models for a wide range of reservoir fluid systems. Solution algorithms and numerical stability problems are discussed for the nonisothermal models that require numerical discretization, unlike the exact analytical solution of the isothermal gradient problem.We discuss the problems related to fluid initialization in reservoir models of complex fluid systems. This involves the synthesis of measured sample data and theoretical models. Specific recommendations are given for interpolation and extrapolation of vertical compositional gradients. The importance of dewpoint on the estimation of a gas/oil contact (GOC) is emphasized, particularly for newly discovered reservoirs in which only gas samples are available and the reservoirs are near-saturated.Finally, we present two field case histories-one in which the isothermal gravity/chemical equilibrium model describes measured compositional gradients in a reservoir grading continuously from a rich gas condensate to a volatile oil, and another example in which the isothermal model is grossly inconsistent with measured data and convection or thermal diffusion has apparently resulted in a more-orless constant composition over a vertical column of some 5,000 ft.

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“…When gas comes out of the solution the resulting oil and the mixture of the displacement fluid, will have relatively similar geometrical locations with respect to original in-situ oil and the fresh injectant. This particular phenomenon has been explained in detail 5 . Furthermore, the theory can also be extended to the condensate cases that gas injection (i.e., rich gas injection/recycling) takes place below the dew point pressure as long as the displacement mechanism is Condensing/Vaporizing drive.…”

Section: Selection Of Possible Miscible Agentsmentioning

confidence: 81%

Gas Blending for Miscible Gasfloods in South Oman

Deinum¹,

Dindoruk

O'Dell

2007

SPE Middle East Oil and Gas Show and Conference

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TX 75083-3836, U.S.A., fax 01-972-952-9435. AbstractHow to ensure that miscibility of oil and gas is achieved in each reservoir is a fundamental issue for miscible gasfloods involving different oil reservoirs with varying fluid properties. This paper reports on all the work done to help decide on how to optimally blend available gas such that miscibility can be achieved in all reservoirs with appropriate focus on the first reservoirs to be flooded. These studies have resulted in an investment decision to undertake a miscible gasflood already in 2005, whereas initial production from four reservoirs had only started in March 2004. Main components of this paper are: (1) Design of experiments for a wide spectrum of fluids (from near-critical systems to black oil systems) using miscible sour gas-blends while minimizing cost and the time spent on the experiments. (2) Acquisition, interpretation of the data (3) Utilization of the data for reservoir engineering/design calculations using a consistent approach for a cluster of sour reservoir fluids, (4) Recommendations based on the experimental data and calibrated simulation models.

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Miscibility Variation in Compositionally Grading Reservoirs

Cited by 44 publications

References 13 publications

Interplay of Phase Behavior and Numerical Dispersion in Finite-Difference Compositional Simulation

Interplay of Phase Behavior and Numerical Dispersion in Finite-Difference Compositional Simulation

Compositional Grading—Theory and Practice

Gas Blending for Miscible Gasfloods in South Oman

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